1. Introduction
The cattle tick Riphicephalus (Boophilus) microplus is one of the most important ectoparasites because it causes economical losses of several million dollars to the world economy [1].
In Mexico, among the 77 especies of ticks identified, R. (Boophilus) microplus and Amblyoma cajennense are the most oustanding for cattle owners [2]. Ref. [3] mentioned that R. (Boophilus) microplus, present in 53% of the national territory, is distributed mainly in low tropical areas.
The control of this tick in Mexico is based on the use of ixodicides [4,5]; however, nowadays a considerable number of them produce resistance due to excesive and inadequate use.
Although several tests to determine the suceptibility to a particular acaricide are available, the Adult Inmersion Test (AIT) [6] is the test of worldwide reference which is approved by FAO for the determination of resistance [7]. Another test frequently employed is the Larval Paquet Test (LPT) [8], which determines the percentage of mortality in larvae treated with therapheutic concentrations of an acaricide.
Very recently our group from the Chemistry School of the National Autonomous University of Mexico (UNAM), has sinthesized a compound coded 712-BF-016 which was selected among 85 other molecules having the following characteristics: White powder, Molecular weight 223.66, melting point 48˚C - 50˚C, soluble in EtOH, DMSO, C6H6, AcOEt, Acetone, Trichloroethane and slightly soluble in water. Its molecular formula is: C10H10CIN30.
Chemical structure.
The present study was aimed at evaluating the ixodicide efficacy of compound 712-BF-016 against Rhipicephalus (Boophilus) microplus ticks in vitro and in cattle.
2. Material and Methods
2.1. Location of the Study
All in vitro tests were carried out at the Parasitology Department of the Veterinary School and the field study in cattle was undertaken at the “Santa Cruz” ranch located at Ayotoxco, Puebla (southeastern part of Mexico).
2.1.1. First Experiment (Larval Packet Test (LPT)) [8]
Five discriminant doses of the experimental compound (1%, 0.50%, 0.25%, 0.13%, 0.06%) were prepared for the treatment groups and an untreated control group (using 30 ml of vegetal oil and 60 ml of trichloroetilene) was included. For the larval packets Whatman No. 1 filters (7.5 × 8.5 cm) were used, the name of the compound being identified for each dilution. Then papers were impregnated with the compound dilutions and each dilution was carried out three times.
The packets were bent with the impregnated face on the inside site. Finally the free ends were sealed with a paper pressing holder.
With the aid of a small paintbrush taking approximately 100 fourteen-day old larvae were placed inside the packet. All packets were incubated at 28˚C ± 2˚C for 24 hours with an 80% - 90% relative humidity. With the aid of a table counter dead and live ticks from each packet were counted to estimate the response percentages of mortality for each dilution.
Parameters evaluated. To calculate the Mortality Index due to the effect of the experimental ixodicide and the larval survival, the following formula was applied: [4].
To calculate the average mortality, the following formula was employed:
2.1.2. Second Experiment Adult Inmersion Test (AIT) [6]
Five discriminant doses were prepared with the experimental compound (1%, 0.50%, 0.25%, 0.13% y 0.06%) leaving one untreated control group.
The doses were then placed in individual beakers, and 10 adult ticks were immersed in each of the beakers for 30 minutes. Five repeats were carried out for each dose and the control group was only immersed in distilled watter.
After the ticks were sieved and dried with paper towels , they were then stuck on the dorsal face with scotch tape after being placed in a Petri dish. The ticks were then incubated at 28˚C ± 2˚C and 80% - 90% relative humidity for seven days. After incubation, the number of ticks which ovoposited per group were counted. In order to obtain the complete oviposition the ticks were then incubated for another 7 days and the percentage of mortality and the mean weight of ovigerous-mass were obtained.
Efficacy measurement. The efficacy was calculated by means of the formula (see the bottom of the page) [10].
2.1.3. Field Test in Cattle
Twenty-four crossbred steers with an average weight of 200 kg were used. Each animal was infested with 40,000 susceptible larvae of R. (Boophilus) microplus obtained from 2 young cattle previously infested with ticks. Twenty-one days after the infestation, the engorged ticks present were counted, the animals having been divided into 4 groups (G) of 6 animals each for treatment.
• G1 received a single aspersion with the experimental compound formulated at 16%. It was applied with the aid of an aspersion bomb in a total volume of 4 liters/animal.
• G2 was treated in a manner similar to that of G1 but the concentration of the experimental compound was 20%.
• G3 treated with a commercial ixodicide (TlalaxinShark®) containing Cipermethrin at 16%, was used as a drug of reference.
• G4 was an untreated control.
Percentage of ticks that oviposited [11].
The oviposition index was calculated by the following formula: [11].
where: 20,000 = Number of larvae present in 1 gram of eggs.
C.F. of % of hatching = Centesimal fraction of the % of hatching.
The percentage of hatching inhibition was calculated according to [11].
where:
OP/T = Estimated reproduction of the control group.
OP/t = Estimated reproduction of the experimental group.
The percentage of hatching was established as follows: [10].
where: C = eggshells, E = eggs.
Finally the efficacy was calculated as above mentioned with the in vitro tests.
3. Results and Discussion
In vitro percentage of larval mortality (LPT).
Table 1 shows that the more incremented were the concentrations with the experimental compound higher percentage of mortality was obtained. Here concentrations at 1% produced a 91.1% of mortality while the average mortality percentage was 91.6.
However, when the other tested concentrations were analyzed, it was observed that the efficacy decreased gradually and the percentages of efficacy came down to considerably low levels.
The statistical analysis indicated important differences among treatments, the pattern being repeated in the case of average mortality. There are significant differences between treatments including the control group.
Table 2 shows that as the experimental compound was tested against adult ticks (AIT), the exerted efficacy measured as a percentage of mortality was high (97.65%) at a concentration of 1%, the efficacy gradually decreasing with the subsequent concentrations. Here it is important to note that in most of the decreased concentrations, the efficacy remained constant with values close to the 1% concentration, (95.54%, 91.98%, 85.94% and 77.51%), thus showing a better constant effect than that obtained with the larval packet test (LPT).
Statistical differences in efficacy were detected at all concentrations, except at 1% and 0.5%.
With regard to the mean weight of eggs from adult treated ticks, no differences were determined at 1% and 50% concentrations but the rest showed to be statistically different. (Table 2).
Results obtained in the field test with cattle, where the exerted efficacy was of 61.78% for the experimental compound formulated at a 16% concentration and 76.4% for the formulation prepared at a 20% concentration, demonstrated that the commercial compound containing a 16% cipermethrin showed an 85.3% efficacy (Table 3).
The statistical analysis showed that the mean number of ticks before and after the treatment indicated significant differences among the given concentrating the most being efficient cipermethrin at 16%. (Table 3).
Table 1. In vitro Percentage of larval mortality of Riphicephalus (Boophilus) microplus with the experimental compound 712-BF-016 by mean of the Larval Packet Test.
a,b,c,d,eDifferent superscripts indicate statistical difference (P < 0.05).
Table 2. In vitro Percentage Mortality of adult Riphicephalus (Boophilus) microplus with the experimental compound 712-BF-016.
a,b,c,dDifferent superscripts indicate statistical difference (P < 0.05).
Table 4 shows that even when the 20% formulation gave on apparently better performance, it was observed that when the data of the Oviposition Index (0.28) and the Percentage of the Inhibition of the Oviposition (50.1) were related, the results indicated that the formulation of the experimental compound applied at 16% was better since this group had a better effect on mortality.
When the oviposition index and the percentage of inhibition of oviposition were compared with the concentrations of 16% of compound 712-BF-016 and 16% cipermenthrin no important differences were noted. However, the percentage of inhibition showed statistical differences when the three treatment-concentrations were analyzed (Table 4).
With regard to the percentage of hatching from tickeggs collected from the steers after the treatment, the information revealed that the lower percentage of egg hatching per group was obtained from the 16% experimental formulation (50.57%) and the highest percentage of tick egg hatching was with that of 16% cipermethrin (74.89%). This demonstrates that under these circumstances cipermethrin did not have a high effect on the hatching of the treated tick-eggs.
Looking at the percentage of hatching, significant differences were observed in all evaluated groups (Table 5).
It can be said generally that the efficacy exerted by the experimental compound under in vitro conditions proved to be satisfactory, particularly against adult ticks. However, the efficacy exerted by the experimental compound under field conditions in cattle showed neither a similar correlation or a similarity with the in vitro results. Possibly the excipient used to formulate the experimental compound was not suitable and therefore the efficacy obtained was lower.
Further studies should be conducted using different excipients aimed at determining whether the ixodicide efficacy of the experimental compound can increase or not.
Table 3. Percentage efficacy of compound 712-BF-016 and Cipermethrin against Riphicephalus (Boophilus) microplus ticks in artificially infested cattle.
a,b,c,dDifferent superscripts indicate statistical difference (P < 0.05).
Table 4. Oviposition Index and Percentage inhibition of the oviposition of collected ticks from cattle treated with compound 712-BF-016 or with Cipermehtrin.
a,b,c,dDifferent superscripts indicate statistical difference (P < 0.05).
Table 5. Hatching percentage of eggs from Riphicephalus (Boophilus) microplus ticks collected from cattle treated with compounds 712-BF-016 or cipermethrin.
a,b,c,dDifferent superscripts indicate statistical difference (P < 0.05).
4. Conclusion
The experimental compound 712-BF-016 evaluated against Riphicephalus (Boophilus) microplus ticks showed high efficacy against larvae and adult ticks in vitro. However, this exerted efficacy was considerably low when a field test in cattle was performed.
5. Acknowledgements
Study supported by the project PAPIIT-DEGPA-UNAM IN201710.
The authors are indebted to Ing. Rafael García Bonilla for letting us use his ranch to carry out the field study.