Accuracy and reliability of a videogrammetry system in the analysis of displacement of Wistar rats

Silva Junior, Osvaldo Tadeu da; Santiago, Paulo Roberto; Curiacos, Jose Alexandre Almeida Leme; Santos, Julio Wilson dos

doi:10.1590/S1980-6574201700030006

Abstract

Aims

The behavior of laboratory animals has been studied through displacement, with different objectives by researchers.

Methods

Although different methods have already been used in the tracking of laboratory animals, manual tracking mode videogrammetry for 2D analysis of displacement has not been observed in animal studies. The aim of this study was to verify the accuracy and reliability of determining the displacement of Wistar rats by means of videogrammetry software Dvideo. The accuracy (between the known distance and distance traced) was determined by 3 different evaluators twice consecutive, by videoing a course of 10 meters in the enriched environment together with further analysis of the displacement of the midpoint marked on an apparatus. To calculate reliability (accuracy of the measurement system) and reproducibility (precision of the evaluators) to obtain the ratio of precision to tolerance (P/T), eight animals were filmed for 10 minutes in the enriched environment and analysis of distance covered by one of the animals by three different reviewers thrice consecutive.

Results

The results obtained in the course of 10 meters of the known distance demonstrated accuracy of 0.10 m, precision of 0.05 m, and bias of 0.07 m. In the reliability test during the 10 minutes of displacement (m) of animal, the ratio of precision to tolerance (P/T) = 0.1 m was found between three different evaluators, demonstrating adequate capacity of the measure.

Conclusion

The manual tracking mode of the Dvideo presented high reliability and it can be employed for the displacement analysis of studies with rat experimental models.

Keywords
displacement; videogrammetry; 2D analysis

Introduction

The behavior of laboratory animals has been studied by means of experimental models with different objectives¹1 Kilkenny C, Browne WJ, Cuthill IC, Emerson M, Altman DG. Improving Bioscience Research Reporting: The ARRIVE Guidelines for Reporting Animal Research. PLoS Biol. 2010; 8(6). . Different methods have been used for the analysis of displacement, such as an ultrasonic activity monitor²2 Akaka WH, Houck BA.The use of an ultrasonic monitor for recording locomotor activity. Behav Res Meth Instrum Comput. 1980;12(5): 514-516. , electronic device³3 Tarpy RM, Murcek RJ. An electronic device for detecting activity in caged rodents. Behav Res Meth Instrum Comput. 1984; 16(4): 383-387. , calculation of the position of the center of gravity on the ground⁴4 Gapenne O, Simon P, Lannou J.A simple method for recording the path of a rat in an open field. Behav Res Meth Instrum Comput. 1990; 22(5): 443-448. , and infrared detection⁵5 Clarke RL, Smith RF, Justesen DR. A programmable proximity-contact sensor to detect location or locomotion of animals. Behav Res Meth Instrum Comput. 1992; 24(4): 515-518. . However, these methods present limitations to analyze the behavior of animals in a group, or interacting with each other. They can track only one animal at a time. Besides that, these methods require a simple background (in terms of their gray scale values) and can deal only a limited range of experimental setups⁷7 Noldus LP, Spink AJ, Tegelenbosch RA. EthoVision: A versatile video tracking system for automation of behavioral experiments. Behav Res Meth Instrum Comput. 2001; 33(3): 398-414. , making tracking in the dark difficult. On the other hand, analysis by videogrammetry in manual tracking mode allows the recording of several animals in a cage or enriched environment to analyze the behavior of animals in a group through the individual analysis of the animals and it enables the tracking during the dark cycle.

Initially employed to analyze human movement⁶6 Barros RML, Brenzikofer R, Leite NJ, Figueroa PJ. Development and evaluation of a system for three-dimensional kinematic analysis of human movements. Res Biomed Eng. 1999; 15(1): 79-86., the use of videogrammetry for the analysis of displacement continued to be used in experimental animal models⁷7 Noldus LP, Spink AJ, Tegelenbosch RA. EthoVision: A versatile video tracking system for automation of behavioral experiments. Behav Res Meth Instrum Comput. 2001; 33(3): 398-414. . Although, in human studies, acceleration, speed, and the analysis of angles of body segments are important parameters for some areas of knowledge. In experiments with animals, the displacement is an important parameter in the study of behavior. Classified as spontaneous physical activity, locomotor behavior is a key element in the daily lives of animals, required for survival and homeostasis⁸8 Garland T, Schutz H, Chappell MA, Keeney BK, Meek TH, Copes LE, et al. The biological control of voluntary exercise, spontaneous physical activity and daily energy expenditure in relation to obesity: Human and rodent perspectives. J Exp Biol. 2010; 214(2): 206-229. . In recent decades, the development of analytical methods to analyze displacement by videogrammetry has been used in studies with different objectives: to understand the effects of psychostimulants⁹9 Marin MT, Zancheta R, Paro AH, Possi AP, Cruz FC, Planeta CS. Comparison of caffeine-induced locomotor activity between adolescent and adult rats. Eur J Pharmacol. 2011; 660(2-3): 363-367. , different environments¹⁰10 Xie H, Wu Y, Jia J, Li G, Zhang Q, Yu K, et al. Enrichment-induced exercise to quantify the effect of different housing conditions: A tool to standardize enriched environment protocols. Behav Brain Res. 2013; 249: 81-89. , food restriction¹¹11 Perez-Leighton CE, Grace M, Billington CJ, Kotz CM. Role of spontaneous physical activity in prediction of susceptibility to activity based anorexia in male and female rats. Physiol Behav. 2014; 135: 104-111. , different conditions of housing¹²12 Augusiak J, Brink PJ. Studying the movement behavior of benthic macro invertebrates with automated video tracking. Ecol Evol. 2015; 5(8): 1563-1575., and drugs¹³13 Smethells JR, Swalve N, Brimijoin S, Gao Y, Parks RJ, Greer A, et al. Long-Term Blockade of Cocaine Self-Administration and Locomotor Activation in Rats by an Adenoviral Vector-Delivered Cocaine Hydrolase. J Pharm Exp Ther. 2016; 357(2): 375-381.

Although automated videogrammetry is an effective method for the analysis of displacement, this technological progress requires high cost equipment. On the other hand, the manual tracking mode of displacement analysis of animals is also a good option, since it uses the same method (videogrammetry), but with much lower investment than the automatic method. The semi-automatic method has been used in studies requiring high precision, such as angular kinematics of movement¹⁴14 Barbieri FA, Gobbi LT, Santiago PR, Cunha SA. Performance comparisons of the kicking of stationary and rolling balls in a futsal context. J Sport Biomech. 2010; 9(1): 1-15. and measures of distance and velocity in sport¹⁵15 Bueno MJ, Caetano FG, Pereira TJ, Souza NM, Moreira GD, Nakamura FY, et al. Analysis of the distance covered by Brazilian professional futsal players during official matches. J Sport Biomech. 2014; 13(3): 230-240. ,¹⁶16 Pereira TJ, Nakamura FY, Jesus MT, Vieira CL, Misuta MS, Barros RM, et al. Analysis of the distances covered and technical actions performed by professional tennis players during official matches. J Sports Sci. 2016; 1-8. , showing various possibilities of application for analysis in three dimensions (3D), using at least two cameras. In experimental models with rats, displacement analysis can be performed in two dimensions (2D), with only one camera, since it is possible to position the camera above the cage or environment in which the animals are located and obtain images for analysis of the displacement of the animals during the spontaneous physical activity. However, the accuracy and reliability of the manual tracking mode method of video analysis, using 2D videogrammetry for analysis of displacement, have not been verified in animal studies.

Accuracy is widely used to indicate the quality of an observed size or estimated parameter, defined as the degree of proximity of an estimate with the parameter, true value¹⁸18 Mikhail EM, Ackerman FE. Observations and least squares. New York: IEP; 1976.. Therefore, the analysis of the measurement system is a fundamental component to guarantee the reliability of the results that it produces. As an option, it is possible to plan studies of the capacity of a measuring system to investigate two measurement error components, through the reliability and reproducibility parameters (R&R)¹⁹19 Montgomery DC. Introduction to statistical quality control. Hoboken, NJ: Wiley; 2004.. Thus, R&R is a tool used for the analysis of the variability associated with the contribution of instrumentation, environmental conditions, and evaluators, in a particular measurement process. To our knowledge, none of the displacement analysis systems used in the experimental model with rats presented a measure of accuracy and reliability.

Reliability of measurement results is directly linked to knowledge and control of the characteristics of the measuring system. In this way, verifying the accuracy and reliability of videogrammetry for the measurement of displacement in the animal experimental model is primordial. The aim of this study was to verify the accuracy and reliability of the determination of the distance of Wistar rats using manual tracking mode.

Materials and methods

Animals

Wistar rats (RattusNorvegicus Albinus Wistar), of 120 days of age from the Vivarium of the São Paulo State University (UNESP) Botucatu campus, were used in this study. The animals were allocated to a cage (enriched environment) measuring 128 x 58 x 45 cm (8 animals/environment) in the vivarium of the Unisalesiano University Center, Lins Campus. The enriched environment comprised a group of animals and inanimate objects (racing wheel, tunnel, bridges, balls, and others) that facilitated sensory, motor, and social cognitive stimulation²⁰20 Sztainberg Y, Chen A. An environmental enrichment model for mice. Nat Protoc. 2010; 5(9): 1535-1539. . The temperature (25 ± 1°C) and luminosity (light/dark cycle 12/12 h) of the vivarium were tracked and the animals had free access to water and food. The procedures of this study were in accordance with the guidelines stated by the Ethical Principles in National Council for Animal Experimentation and control (CONSEA) and approved by the Commission of ethics in the use of Animals-CEUA-UNISALESIANO (Protocol no. 09/2015, in 8/27/2015). Our research procedures were carried out strictly in accordance with these approved guidelines.

Acquisition of the images to calculate the accuracy

An IP Camera 1.3 MP Infrastructure 30M (1280 x 720) was fixed in the center top of the enriched environment one meter above the cage by means of a metal bracket attached to the ceiling. The recording was managed by Capture Software (Citrox), set to a frequency of 60 Hz acquisition (image resolution of 720 x 480).

Accuracy determination was performed in the same enriched environment space without the inanimate objects. A 10 meters line of continuous nylon was distributed randomly in the background. An apparatus containing a wooden rod with a mini fabric bag (4 x 6 cm) at its end, marked with a red dot of 0.5 cm in RADIUS, as a reference to the center of mass, was used for the filming of an appraiser walking the path of 10 m (Figure 1) .

Figure 1
Enriched environment, with the nylon line of 10 meters distributed randomly in the background, markings of the extremities (calibration points in red) and the rod with the mini-bag marked with the midpoint.

After the acquisition of the video of the 10 meters route and calibration process that took as a reference the four points marked in the corners of the box of the enriched environment, whose actual distances had been previously measured, the "X" axis represented the length of the enriched environment, and the "Y" axis represented its width. Then, three evaluators conducted two measurements each of the total displacement by the midpoint, using the manual tracking mode of the software Dvideo⁶6 Barros RML, Brenzikofer R, Leite NJ, Figueroa PJ. Development and evaluation of a system for three-dimensional kinematic analysis of human movements. Res Biomed Eng. 1999; 15(1): 79-86.,¹⁷17 Barros RML, Misuta MS, Menezes RP, Figueroa PJ, Moura FA, Cunha SA, et al. Analysis of the Distances Covered by First Division Brazilian Soccer Players Obtained with an Automatic Tracking Method. J Sports Sci Med. 2007; 6(2): 233-242.. Subsequently, a file was created with the screen coordinates of the ordered pairs (X, Y) in 2D, of the movement of the rod around the markings in the environment background and, from this information, the displacement of the midpoint was calculated to obtain the total distance (m) (Figure 2), in a specific routine developed in Matlab(r) software 2014a (Match Works Inc, Massachusetts, United States).

Figure 2
Image of the 10 meters route from the X, Y coordinates in 2D, obtained by one of the three evaluators. Green dot = beginning of the trace; red dot = end of the trace.

Accuracy test

The total distance of the displacement by the rod was traced, and the accuracy (Equation 1), bias (systematic error-equation 2) and precision (Equation 3) measured from the calculation of the distance obtained through the experimental formulas presented below:

where: a = accuracy; b = bias; p = precision; µ = actual value; m_i = (i = 1, ..., N) = observed value of the measure obtained experimentally; = average value of N measures; N = number of repetitions of the experiment.

Calculation of Displacement

The filming of the enriched environment, containing eight animals, was used for the analysis of the displacement. However, only the displacement of one animal was used in the analysis. A video with a duration of 10 minutes was recorded to determine the distance which the animal moved in the enriched environment. The analysis was carried out by three different evaluators who performed three measurements each of the same video. The same procedures of reconstruction in 2D and the calculations of the "X" and "Y" coordinates were performed as described above, for the test of accuracy. As in the test of accuracy, a red point was marked as a reference on the animal, to standardize the trace. The result of the tracking of one animal by one of the evaluators is presented in Figure 3.

Figure 3
Image of the tracing of one rat in the enriched environment during the 10 minutes screening. Green dot = beginning of the trace; red dot = end of the trace.

Reliability and reproducibility

The reliability and reproducibility by videogrammetry in manual tracking mode of the Dvideo were calculated as proposed by method (R&R)¹⁹19 Montgomery DC. Introduction to statistical quality control. Hoboken, NJ: Wiley; 2004.. Thus, the reproducibility refers to the variability of the averages of the measurements obtained by different evaluators (either in different time periods, different environments, or under different conditions) when performing repeated times with the same measuring instrument. From the R&R it is possible to obtain the components of the standard deviation of the measurement error (σ _ meter) and calculate the precision to tolerance ratio (P/T), where a measurement system needs to be able to measure accurately enough to interpret the correct measure between the evaluators. P/T values equal or less than 0.1 indicate adequate capacity of the measure. The trace data were obtained from rat displacement for determining the following parameters:

σ² measurement error = σ² measurer (equation 3) = σ² repeatability (equation 1) + σ² reliability (equation 2) and the 6σ measurer ratio (total tolerance range of precision-equation 4) with the following:

where: = Average of the three average amplitudes of the evaluators, = Mean amplitude of measures 1 and 2 of evaluator n° 1; = Mean amplitude of measures 1 and 2 of evaluator n° 2; = Mean amplitude of measures 1 and 2 of evaluator n° 3; d₂= Factor for size 2 samples (1,693), = Mean of the average value of the measures of the evaluator n° 1, = Mean of the average value of the measures of the evaluator n° 2, = Mean of the average value of the measures of the evaluator n° 3, = Amplitude of a sample of 3 sizes, P = precision, T = tolerance, LSE = upper specification limit (average plus standard deviation), LIE = lower specification limit (average plus standard deviation).

Results

The results of measurements performed during the manual tracking mode by three evaluators presented acceptable values, in comparing between known distance and distance traced (Table 1).

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Table 1
Values obtained by the evaluators from distance of 10 meters.

Individual results as well as the mean and standard deviation to the measurements obtained by the evaluators during the 10 minute of the rat displacement are shown in Table 2. According to the results observed, the difference between the maximum and minimum values between the evaluators is very small, resulting in the coefficient of variation (CV = 0,06).

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Table 2
Values obtained by the evaluators during the 10 minute of the displacement rat.

The total distance traveled, that is the sum of the three different 10 minutes animal tracking results performed by the different raters found was 40.08 meters for the rater n° 1, 40.10 meters (maximum value) evaluator n° 2 and 40.01 meters (minimum value) for evaluator 3. The largest difference found in the value of the distance traveled between the evaluators was 0.10 meters (0.27%). The figure 4 show the result of the tracking of the animal by three evaluators during the first attempt.

Figure 4
Image of the tracing of one rat in the enriched environment during the 10 minutes of the tracking. Red = evaluator n°1; green = evaluator n°2 and blue = evaluator n° 3.

Table 3 presents the values of the variables of error in the accuracy test, in which the tracing of a known distance of 10 meters made at the bottom of the box of the enriched environment was calculated. The accuracy was 1.0%. Table 4 presents the error values obtained in the test for reliability through R&R of one rat in the enriched environment during the 10 minutes of tracking. The P/T ratio remained within the tolerance limit (10%).

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Table 3
values obtained in the calculations of accuracy, precision, and bias of the first experiment.

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Table 4
Data of the variables of the σ² measurement error for the reliability of the second experiment.

Discussion

Methodologies based on videogrammetry allow to investigate and to better understand various phenomena in laboratory animals related to the displacement, such as: the effect of psychostimulant drugs on locomotion¹³13 Smethells JR, Swalve N, Brimijoin S, Gao Y, Parks RJ, Greer A, et al. Long-Term Blockade of Cocaine Self-Administration and Locomotor Activation in Rats by an Adenoviral Vector-Delivered Cocaine Hydrolase. J Pharm Exp Ther. 2016; 357(2): 375-381, quantify the influence of the environment on physical activity levels²¹21 Verwey M, Robinson B, Amir S. Recording and Analysis of Circadian Rhythms in Running-wheel Activity in Rodents. J Vis Exp. 2013; (71). , improve animal study protocols²¹21 Verwey M, Robinson B, Amir S. Recording and Analysis of Circadian Rhythms in Running-wheel Activity in Rodents. J Vis Exp. 2013; (71). , to study memory information and spatial orientation¹⁰10 Xie H, Wu Y, Jia J, Li G, Zhang Q, Yu K, et al. Enrichment-induced exercise to quantify the effect of different housing conditions: A tool to standardize enriched environment protocols. Behav Brain Res. 2013; 249: 81-89. .

The present study was designed to investigate the accuracy and reliability of measurement of displacement of Wistar rats by videogrammetry using manual tracking mode of the Dvideo. The Dvideo interface allows to obtain the screen coordinates of a given object through an operator, pointing the computer screen to the object whose coordinate you want to obtain, with the help of the mouse. It is an option used where it is not possible to perform the measurement automatically.

The findings of this study, accuracy of 1% (0.10 m) and reliability through the calculations of R&R (P/T = 0.10 m) demonstrated that manual tracking mode of the Dvideo 2D videogrammetry is a good method to analysis of displacement of Wistar rats.

The accuracy 0.10 m, precision (0.05 m) and Bias (0.07 m) corroborate with previous studies⁶6 Barros RML, Brenzikofer R, Leite NJ, Figueroa PJ. Development and evaluation of a system for three-dimensional kinematic analysis of human movements. Res Biomed Eng. 1999; 15(1): 79-86.,¹⁷17 Barros RML, Misuta MS, Menezes RP, Figueroa PJ, Moura FA, Cunha SA, et al. Analysis of the Distances Covered by First Division Brazilian Soccer Players Obtained with an Automatic Tracking Method. J Sports Sci Med. 2007; 6(2): 233-242. in which through videogrammetry has been verified the reliability of the software Dvideo in determining the displacement in soccer players and analysis of human movements, respectively, demonstrating its flexibility of application. Although the situations of analysis of the above studies are different, displacement in soccer field, movement of human body segments and, of the present study, with rat displacement, in all situations the use of Dvideo software presented accuracy. Specifically, in the studies on displacement analysis in the experimental model with rats, to our knowledge, no study presented the accuracy and reliability of the measure in its different methods, such as an ultrasonic activity monitor²2 Akaka WH, Houck BA.The use of an ultrasonic monitor for recording locomotor activity. Behav Res Meth Instrum Comput. 1980;12(5): 514-516. , electronic device³3 Tarpy RM, Murcek RJ. An electronic device for detecting activity in caged rodents. Behav Res Meth Instrum Comput. 1984; 16(4): 383-387. , calculation of the position of the center of gravity on the ground⁴4 Gapenne O, Simon P, Lannou J.A simple method for recording the path of a rat in an open field. Behav Res Meth Instrum Comput. 1990; 22(5): 443-448. , and infrared detection⁵5 Clarke RL, Smith RF, Justesen DR. A programmable proximity-contact sensor to detect location or locomotion of animals. Behav Res Meth Instrum Comput. 1992; 24(4): 515-518. . Therefore, the comparison of our results with results from other studies with animal is limited. This is the first study that presents the accuracy of the displacement analysis in the experimental model with rats, demonstrating the reliability of the Dvideo system, through manual tracking mode, for use in studies with displacement in the experimental model with rats.

The analysis by videogrammetry allows storage of information and analyze the behavior of several rats allocated in the same environment, which is not possible to do with the methods applied in previous studies, such as ultrasonic activity monitor²2 Akaka WH, Houck BA.The use of an ultrasonic monitor for recording locomotor activity. Behav Res Meth Instrum Comput. 1980;12(5): 514-516. , electronic device³3 Tarpy RM, Murcek RJ. An electronic device for detecting activity in caged rodents. Behav Res Meth Instrum Comput. 1984; 16(4): 383-387. , calculation of the position of the center of gravity on the ground⁴4 Gapenne O, Simon P, Lannou J.A simple method for recording the path of a rat in an open field. Behav Res Meth Instrum Comput. 1990; 22(5): 443-448. , and infra-red detection⁵5 Clarke RL, Smith RF, Justesen DR. A programmable proximity-contact sensor to detect location or locomotion of animals. Behav Res Meth Instrum Comput. 1992; 24(4): 515-518. . In those studies cited above, the rat is evaluated in isolation, without interaction with others animals. The videogrammetry system allows the displacement analysis considering the animal's interaction with other animals and the environment, which can be manipulated by the researcher. Inside the videogrammetry analysis, the automatic method has been used in studies on the behavior in the light/dark cycle²¹21 Verwey M, Robinson B, Amir S. Recording and Analysis of Circadian Rhythms in Running-wheel Activity in Rodents. J Vis Exp. 2013; (71). ,²²22 Aslani S, Harb MR, Costa PS, Almeida OF, Sousa N, Palha JA. Day and night: Diurnal phase influences the response to chronic mild stress. Front Behav Neurosci. 2014 ; 8:82.Acesso em 01/11/2016: In: Pubmed; PMID 24672446., distance and speed¹³13 Smethells JR, Swalve N, Brimijoin S, Gao Y, Parks RJ, Greer A, et al. Long-Term Blockade of Cocaine Self-Administration and Locomotor Activation in Rats by an Adenoviral Vector-Delivered Cocaine Hydrolase. J Pharm Exp Ther. 2016; 357(2): 375-381,¹⁰10 Xie H, Wu Y, Jia J, Li G, Zhang Q, Yu K, et al. Enrichment-induced exercise to quantify the effect of different housing conditions: A tool to standardize enriched environment protocols. Behav Brain Res. 2013; 249: 81-89. . On the other hand, to our knowledge, the videogrammetry with manual tracking mode had not yet been tested in animal experiments. In the present study, the manual tracking mode of analysis presented reliability and accuracy. In addition, the system analyzed in present study is a low-cost option compared to the automatic method, which has a high commercial value, while the Dvideo software was developed for research purposes and made available free of charge.

Videogrammetry manual tracking mode reliability verified through the study of parameter R&R¹⁸18 Mikhail EM, Ackerman FE. Observations and least squares. New York: IEP; 1976. demonstrated to be useful for evaluating the tool used in the experiment, once your setting was 0.1 meter, which indicates an adequate measurement capability. The index R&R is used to verify the suitability of the measuring system, determined by reason of 6σ_meter to the total tolerance range or precision to tolerance ratio (P/T). Once the ratio P/T is influenced by the reliability (basic accuracy associated with the measuring tool itself) and reproducibility (variability due to the fact that the measuring system to be used by different raters), the result found for reproducibility (0,05 ) with regard to reliability (0,08) makes it clear that the use of videogrammetry using the Dvideo between different evaluators have good reliability.

The method manual tracking mode videogrammetry , employed in this study to rats, in addition to presenting low cost, accuracy and reliability verified, it may be useful for research in different experimental models with rats and other species, such as the analysis of the social behavior of Wistar rats kept in enriched environment, analysis in isolated situations, such as labyrinths, or any other condition where it is possible to carry out the acquisition of image with top view.

Finally, it is important to note that the present study does not close this topic. The study presents the limitation of evaluating only one animal species, Wistar rats, in an enriched environment. Thus, although the accuracy and reliability of the Dvideo system has been confirmed, further studies should be carried out, with animals of another species, such as mice, mainly because of the difference in body size and the displacement velocity between the two animal species, rat and mice, and the to analyze in other environment.

Conclusion

The high reliability of system tested in present study demonstrate that the videogrammetry manual tracking mode of the Dvideo can be useful to the analysis of distance traveled in experimental models that study the effects of different variables on animal behavior, such as social interaction, drugs, food and diet, physical activity and exercise among others.

References

¹
Kilkenny C, Browne WJ, Cuthill IC, Emerson M, Altman DG. Improving Bioscience Research Reporting: The ARRIVE Guidelines for Reporting Animal Research. PLoS Biol. 2010; 8(6).
²
Akaka WH, Houck BA.The use of an ultrasonic monitor for recording locomotor activity. Behav Res Meth Instrum Comput. 1980;12(5): 514-516.
³
Tarpy RM, Murcek RJ. An electronic device for detecting activity in caged rodents. Behav Res Meth Instrum Comput. 1984; 16(4): 383-387.
⁴
Gapenne O, Simon P, Lannou J.A simple method for recording the path of a rat in an open field. Behav Res Meth Instrum Comput. 1990; 22(5): 443-448.
⁵
Clarke RL, Smith RF, Justesen DR. A programmable proximity-contact sensor to detect location or locomotion of animals. Behav Res Meth Instrum Comput. 1992; 24(4): 515-518.
⁶
Barros RML, Brenzikofer R, Leite NJ, Figueroa PJ. Development and evaluation of a system for three-dimensional kinematic analysis of human movements. Res Biomed Eng. 1999; 15(1): 79-86.
⁷
Noldus LP, Spink AJ, Tegelenbosch RA. EthoVision: A versatile video tracking system for automation of behavioral experiments. Behav Res Meth Instrum Comput. 2001; 33(3): 398-414.
⁸
Garland T, Schutz H, Chappell MA, Keeney BK, Meek TH, Copes LE, et al. The biological control of voluntary exercise, spontaneous physical activity and daily energy expenditure in relation to obesity: Human and rodent perspectives. J Exp Biol. 2010; 214(2): 206-229.
⁹
Marin MT, Zancheta R, Paro AH, Possi AP, Cruz FC, Planeta CS. Comparison of caffeine-induced locomotor activity between adolescent and adult rats. Eur J Pharmacol. 2011; 660(2-3): 363-367.
¹⁰
Xie H, Wu Y, Jia J, Li G, Zhang Q, Yu K, et al. Enrichment-induced exercise to quantify the effect of different housing conditions: A tool to standardize enriched environment protocols. Behav Brain Res. 2013; 249: 81-89.
¹¹
Perez-Leighton CE, Grace M, Billington CJ, Kotz CM. Role of spontaneous physical activity in prediction of susceptibility to activity based anorexia in male and female rats. Physiol Behav. 2014; 135: 104-111.
¹²
Augusiak J, Brink PJ. Studying the movement behavior of benthic macro invertebrates with automated video tracking. Ecol Evol. 2015; 5(8): 1563-1575.
¹³
Smethells JR, Swalve N, Brimijoin S, Gao Y, Parks RJ, Greer A, et al. Long-Term Blockade of Cocaine Self-Administration and Locomotor Activation in Rats by an Adenoviral Vector-Delivered Cocaine Hydrolase. J Pharm Exp Ther. 2016; 357(2): 375-381
¹⁴
Barbieri FA, Gobbi LT, Santiago PR, Cunha SA. Performance comparisons of the kicking of stationary and rolling balls in a futsal context. J Sport Biomech. 2010; 9(1): 1-15.
¹⁵
Bueno MJ, Caetano FG, Pereira TJ, Souza NM, Moreira GD, Nakamura FY, et al. Analysis of the distance covered by Brazilian professional futsal players during official matches. J Sport Biomech. 2014; 13(3): 230-240.
¹⁶
Pereira TJ, Nakamura FY, Jesus MT, Vieira CL, Misuta MS, Barros RM, et al. Analysis of the distances covered and technical actions performed by professional tennis players during official matches. J Sports Sci. 2016; 1-8.
¹⁷
Barros RML, Misuta MS, Menezes RP, Figueroa PJ, Moura FA, Cunha SA, et al. Analysis of the Distances Covered by First Division Brazilian Soccer Players Obtained with an Automatic Tracking Method. J Sports Sci Med. 2007; 6(2): 233-242.
¹⁸
Mikhail EM, Ackerman FE. Observations and least squares. New York: IEP; 1976.
¹⁹
Montgomery DC. Introduction to statistical quality control. Hoboken, NJ: Wiley; 2004.
²⁰
Sztainberg Y, Chen A. An environmental enrichment model for mice. Nat Protoc. 2010; 5(9): 1535-1539.
²¹
Verwey M, Robinson B, Amir S. Recording and Analysis of Circadian Rhythms in Running-wheel Activity in Rodents. J Vis Exp. 2013; (71).
²²
Aslani S, Harb MR, Costa PS, Almeida OF, Sousa N, Palha JA. Day and night: Diurnal phase influences the response to chronic mild stress. Front Behav Neurosci. 2014 ; 8:82.Acesso em 01/11/2016: In: Pubmed; PMID 24672446.

Publication Dates

Publication in this collection
2017

History

Received
14 Dec 2016
Accepted
28 Apr 2017

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ¹
Kilkenny C, Browne WJ, Cuthill IC, Emerson M, Altman DG. Improving Bioscience Research Reporting: The ARRIVE Guidelines for Reporting Animal Research. PLoS Biol. 2010; 8(6).

[2] ²
Akaka WH, Houck BA.The use of an ultrasonic monitor for recording locomotor activity. Behav Res Meth Instrum Comput. 1980;12(5): 514-516.

[3] ³
Tarpy RM, Murcek RJ. An electronic device for detecting activity in caged rodents. Behav Res Meth Instrum Comput. 1984; 16(4): 383-387.

[4] ⁴
Gapenne O, Simon P, Lannou J.A simple method for recording the path of a rat in an open field. Behav Res Meth Instrum Comput. 1990; 22(5): 443-448.

[5] ⁵
Clarke RL, Smith RF, Justesen DR. A programmable proximity-contact sensor to detect location or locomotion of animals. Behav Res Meth Instrum Comput. 1992; 24(4): 515-518.

[6] ⁶
Barros RML, Brenzikofer R, Leite NJ, Figueroa PJ. Development and evaluation of a system for three-dimensional kinematic analysis of human movements. Res Biomed Eng. 1999; 15(1): 79-86.

[7] ⁷
Noldus LP, Spink AJ, Tegelenbosch RA. EthoVision: A versatile video tracking system for automation of behavioral experiments. Behav Res Meth Instrum Comput. 2001; 33(3): 398-414.

[8] ⁸
Garland T, Schutz H, Chappell MA, Keeney BK, Meek TH, Copes LE, et al. The biological control of voluntary exercise, spontaneous physical activity and daily energy expenditure in relation to obesity: Human and rodent perspectives. J Exp Biol. 2010; 214(2): 206-229.

[9] ⁹
Marin MT, Zancheta R, Paro AH, Possi AP, Cruz FC, Planeta CS. Comparison of caffeine-induced locomotor activity between adolescent and adult rats. Eur J Pharmacol. 2011; 660(2-3): 363-367.

[10] ¹⁰
Xie H, Wu Y, Jia J, Li G, Zhang Q, Yu K, et al. Enrichment-induced exercise to quantify the effect of different housing conditions: A tool to standardize enriched environment protocols. Behav Brain Res. 2013; 249: 81-89.

[11] ¹¹
Perez-Leighton CE, Grace M, Billington CJ, Kotz CM. Role of spontaneous physical activity in prediction of susceptibility to activity based anorexia in male and female rats. Physiol Behav. 2014; 135: 104-111.

[12] ¹²
Augusiak J, Brink PJ. Studying the movement behavior of benthic macro invertebrates with automated video tracking. Ecol Evol. 2015; 5(8): 1563-1575.

[13] ¹³
Smethells JR, Swalve N, Brimijoin S, Gao Y, Parks RJ, Greer A, et al. Long-Term Blockade of Cocaine Self-Administration and Locomotor Activation in Rats by an Adenoviral Vector-Delivered Cocaine Hydrolase. J Pharm Exp Ther. 2016; 357(2): 375-381

[14] ¹⁴
Barbieri FA, Gobbi LT, Santiago PR, Cunha SA. Performance comparisons of the kicking of stationary and rolling balls in a futsal context. J Sport Biomech. 2010; 9(1): 1-15.

[15] ¹⁵
Bueno MJ, Caetano FG, Pereira TJ, Souza NM, Moreira GD, Nakamura FY, et al. Analysis of the distance covered by Brazilian professional futsal players during official matches. J Sport Biomech. 2014; 13(3): 230-240.

[16] ¹⁶
Pereira TJ, Nakamura FY, Jesus MT, Vieira CL, Misuta MS, Barros RM, et al. Analysis of the distances covered and technical actions performed by professional tennis players during official matches. J Sports Sci. 2016; 1-8.

[17] ¹⁷
Barros RML, Misuta MS, Menezes RP, Figueroa PJ, Moura FA, Cunha SA, et al. Analysis of the Distances Covered by First Division Brazilian Soccer Players Obtained with an Automatic Tracking Method. J Sports Sci Med. 2007; 6(2): 233-242.

[18] ¹⁸
Mikhail EM, Ackerman FE. Observations and least squares. New York: IEP; 1976.

[19] ¹⁹
Montgomery DC. Introduction to statistical quality control. Hoboken, NJ: Wiley; 2004.

[20] ²⁰
Sztainberg Y, Chen A. An environmental enrichment model for mice. Nat Protoc. 2010; 5(9): 1535-1539.

[21] ²¹
Verwey M, Robinson B, Amir S. Recording and Analysis of Circadian Rhythms in Running-wheel Activity in Rodents. J Vis Exp. 2013; (71).

[22] ²²
Aslani S, Harb MR, Costa PS, Almeida OF, Sousa N, Palha JA. Day and night: Diurnal phase influences the response to chronic mild stress. Front Behav Neurosci. 2014 ; 8:82.Acesso em 01/11/2016: In: Pubmed; PMID 24672446.

Evaluator	Measurements (m)		Mean	Standard deviation
Evaluator	1°	2°	Mean	Standard deviation
1	9,77	9,77	9,77	0,005
2	9,67	9,60	9,64	0,053
3	9,81	9,82	9,81	0,007

Evaluator	Measurements (m)			Mean	Standard deviation
Evaluator	1°	2°	3°	Mean	Standard deviation
1	13,42	13,42	13,24	13,36	0,10
2	13,45	13,27	13,38	13,37	0,08
3	13,42	13,24	13,34	13,33	0,08

Brasil

Brasil

Accuracy and reliability of a videogrammetry system in the analysis of displacement of Wistar rats

Abstract

Aims

Methods

Results

Conclusion

Introduction

Materials and methods

Animals

Acquisition of the images to calculate the accuracy

Accuracy test

Calculation of Displacement

Reliability and reproducibility

Results

Discussion

Conclusion

References

Publication Dates

History