Semi-Automated Tracking of Vibrissal Movements in Free-Moving Rodents Captured by High-Speed Videos
Quantitative analyses of whisker movements provide a
means to study functional recovery and regeneration of mouse facial
nerve after an injury. However, accurate tracking of the mouse whisker
movement is challenging. Most methods for whisker tracking require
manual intervention, e.g. fixing the head of the mouse during a study.
Here we describe a semi-automated image processing method, which
is applied to high-speed video recordings of free-moving mice to track
the whisker movements. We first track the head movement of a mouse
by delineating the lower head contour frame-by-frame that allows for
detection of the location and orientation of the head. Then, a region of
interest is identified for each frame; the subsequent application of a
mask and the Hough transform detects the selected whiskers on each
side of the head. Our approach is used to examine the functional
recovery of damaged facial nerves in mice over a course of 21 days.
[1] S. B. Mehta, D. Whitmer, R. Figueroa, B. A. Williams, and D. Kleinfeld,
“Active spatial perception in the vibrissa scanning sensorimotor system,”
PLoS biology, vol. 5, no. 2, e15, Jan. 2007.
[2] B. Mitchinson, et al., “Active vibrissal sensing in rodents and
marsupials,” Philosophical Transactions of the Royal Society B:
Biological Sciences vol. 366, no. 1581, pp. 3037-3048, Oct. 2011.
[3] M. Brecht, B. Preilowski, and M. M. Merzenich, “Functional architecture
of the mystacial vibrissae,” Behav. Brain Res. Vol. 84, no. 1-2, pp. 81–97,
March 1997.
[4] G. E. Carvell, D. J. Simons, “Biometric analyses of vibrissal tactile
discrimination in the rat,” J Neurosci, vol. 10, no. 8, pp. 2638–2648,
Aug. 1990.
[5] T. Prigg, D. Goldreich, G. E. Carvell, and D. J. Simons, “Texture
discrimination and unit recordings in the rat whisker/barrel system,”
Physiol. Behav., vol. 77, no. 4-5, pp. 671–675, Dec. 2002.
[6] S. P. Most, “Facial Nerve Recovery in bcl2 Overexpression Mice After
Crush Injury,” Arch Facial Plast Surg., vol. 6, no. 2, pp. 82-87, March
2004.
[7] D. M. Lieberman, T. A. Jan, S. O. Ahmad, S. P. Most, “Effects of
Corticosteroids on Functional Recovery and Neuron Survival After Facial
Nerve Injury in Mice,” Arch Facial Plast Surg., vol. 13, no. 2, pp.
117-124, March 2011.
[8] R. W. Lindsay, J. T. Heaton, C. Edwards, C. Smitson, T. A. Hadlock,
“Nimodipine Accelerates Functional Recovery of the Facial Nerve after
Crush Injury,” Arch Facial Plast Surg., vol. 12, no. 1, pp. 49-52, Jan/Feb.
2010.
[9] N. G. Clack, et al., “Automated tracking of whiskers in videos of head
fixed rodents,” PLoS computational biology, vol.8, no. 7, e1002591, July
2012.
[10] J. T. Ritt, M. L. Andermann, and C. I. Moore, “Embodied information
processing: Vibrissa mechanics and texture features shape micromotions
in actively sensing rats,” Neuron, vol. 57, no. 4, pp.599–613, Feb. 2008.
[11] D. H. O’Connor, et al. “Vibrissa-based object localization in head-fixed
mice,” J Neurosci., vol. 30, no. 5, pp. 1947–1967, Feb. 2010.
[12] T. Hadlock, J. Kowaleski, S. Mackinnon, J.T. Heaton, “A novel method
of head fixation for the study of rodent facial function,” Exp Neurol., vol.
205, no. 1, pp. 279-282, May 2007.
[13] T. Hadlock, et al., “Functional Assessments of the Rodent Facial Nerve:
A Synkinesis Model,” The Laryngoscope, vol. 118, no. 10, pp.
1744-1749, Oct. 2008.
[14] T. Hadlock, et al., “The Effect of Electrical and Mechanical stimulation
on the Regenerating Rodent Facial Nerve,” The Laryngoscope, vol. 120,
no. 6, pp. 1094-1102, June 2010.
[15] J. T. Heaton, et al., “A system for studying facial nerve function in rats
through simultaneous bilateral monitoring of eyelid and whisker
movements,” Journal of neuroscience methods, vol. 171, no. 2, pp.
197-206, June 2008. [16] S. Venkatraman, K. Elkabany, J. D. Long, Y. Yao, J. M. Carmena, “A
system for Neural Recording and Closed-Loop Intracortical
Microstimulation in Awake Rodents,” IEEE Transactions on Biomedical
Engineering, vol. 56, no. 1, pp. 15-22, Jan. 2009
[17] S. Roy, J. L. Bryant, Y. Cao, D. H. Heck, “High-precision, three
dimensional tracking of mouse whisker movements with optical motion
capture technology,” Front Behav. Neurosci., vol. 5, no. 27, pp. 1-6, June
2011.
[18] P. M. Knutsen, D. Derdikman, and E. Ahissar, “Tracking whisker and
head movements in unrestrained behaving rodents,” Journal of
neurophysiology, vol. 93, no. 4, pp. 2294-2301, April 2005.
[19] G. Gyory, et al., “An algorithm for automatic tracking of rat whiskers
(Published Conference Proceedings style),” in Proc. International
Workshop on Visual Observation and Analysis of Animal and Insect
Behavior (VAIB), in conjunction with ICPR, Istanbul, 2010, pp.1-4.
[20] I. Perkson, A. Kosir, P. M. Itskov, J. Tasic, and M. E. Diamondg,
“Unsupervised quantification of whisking and head movement in freely
moving rodents,” Journal of Neurophysiology, vol. 105, no. 4,
pp.1950-1962, April 2011.
[21] J. Voigts, B. Sakmann, T. Celikel, “Unsupervised Whisker Tracking in
Unrestrained Behaving Animals,” Journal of Neurophysiology, vol. 100,
no. 1, pp.504-515, July 2008.
[22] N. Otsu, “A threshold selection method from gray-level histograms,”
IEEE Transactions on Systems, Man, and Cybernetics, vol. 9, no. 1, pp.
62-66, Jan. 1975.
[23] T. Shi, G. Ling, and Y. Yan, “Tracing Vocal-fold Vibrations Using
Level-set Segmentation Method. (Published Conference Proceedings
style),” in Proc. 3rd International Conference on Computational and
Mathematical Biomedical Engineering, Hong Kong, 2013, pp. 63-66.
[24] R. O. Duda, and P. E. Hart, “Use of the Hough transformation to detect
lines and curves in pictures.” Communications of the ACM, vol. 15, no. 1
pp. 11-15, Jan. 1972.
[1] S. B. Mehta, D. Whitmer, R. Figueroa, B. A. Williams, and D. Kleinfeld,
“Active spatial perception in the vibrissa scanning sensorimotor system,”
PLoS biology, vol. 5, no. 2, e15, Jan. 2007.
[2] B. Mitchinson, et al., “Active vibrissal sensing in rodents and
marsupials,” Philosophical Transactions of the Royal Society B:
Biological Sciences vol. 366, no. 1581, pp. 3037-3048, Oct. 2011.
[3] M. Brecht, B. Preilowski, and M. M. Merzenich, “Functional architecture
of the mystacial vibrissae,” Behav. Brain Res. Vol. 84, no. 1-2, pp. 81–97,
March 1997.
[4] G. E. Carvell, D. J. Simons, “Biometric analyses of vibrissal tactile
discrimination in the rat,” J Neurosci, vol. 10, no. 8, pp. 2638–2648,
Aug. 1990.
[5] T. Prigg, D. Goldreich, G. E. Carvell, and D. J. Simons, “Texture
discrimination and unit recordings in the rat whisker/barrel system,”
Physiol. Behav., vol. 77, no. 4-5, pp. 671–675, Dec. 2002.
[6] S. P. Most, “Facial Nerve Recovery in bcl2 Overexpression Mice After
Crush Injury,” Arch Facial Plast Surg., vol. 6, no. 2, pp. 82-87, March
2004.
[7] D. M. Lieberman, T. A. Jan, S. O. Ahmad, S. P. Most, “Effects of
Corticosteroids on Functional Recovery and Neuron Survival After Facial
Nerve Injury in Mice,” Arch Facial Plast Surg., vol. 13, no. 2, pp.
117-124, March 2011.
[8] R. W. Lindsay, J. T. Heaton, C. Edwards, C. Smitson, T. A. Hadlock,
“Nimodipine Accelerates Functional Recovery of the Facial Nerve after
Crush Injury,” Arch Facial Plast Surg., vol. 12, no. 1, pp. 49-52, Jan/Feb.
2010.
[9] N. G. Clack, et al., “Automated tracking of whiskers in videos of head
fixed rodents,” PLoS computational biology, vol.8, no. 7, e1002591, July
2012.
[10] J. T. Ritt, M. L. Andermann, and C. I. Moore, “Embodied information
processing: Vibrissa mechanics and texture features shape micromotions
in actively sensing rats,” Neuron, vol. 57, no. 4, pp.599–613, Feb. 2008.
[11] D. H. O’Connor, et al. “Vibrissa-based object localization in head-fixed
mice,” J Neurosci., vol. 30, no. 5, pp. 1947–1967, Feb. 2010.
[12] T. Hadlock, J. Kowaleski, S. Mackinnon, J.T. Heaton, “A novel method
of head fixation for the study of rodent facial function,” Exp Neurol., vol.
205, no. 1, pp. 279-282, May 2007.
[13] T. Hadlock, et al., “Functional Assessments of the Rodent Facial Nerve:
A Synkinesis Model,” The Laryngoscope, vol. 118, no. 10, pp.
1744-1749, Oct. 2008.
[14] T. Hadlock, et al., “The Effect of Electrical and Mechanical stimulation
on the Regenerating Rodent Facial Nerve,” The Laryngoscope, vol. 120,
no. 6, pp. 1094-1102, June 2010.
[15] J. T. Heaton, et al., “A system for studying facial nerve function in rats
through simultaneous bilateral monitoring of eyelid and whisker
movements,” Journal of neuroscience methods, vol. 171, no. 2, pp.
197-206, June 2008. [16] S. Venkatraman, K. Elkabany, J. D. Long, Y. Yao, J. M. Carmena, “A
system for Neural Recording and Closed-Loop Intracortical
Microstimulation in Awake Rodents,” IEEE Transactions on Biomedical
Engineering, vol. 56, no. 1, pp. 15-22, Jan. 2009
[17] S. Roy, J. L. Bryant, Y. Cao, D. H. Heck, “High-precision, three
dimensional tracking of mouse whisker movements with optical motion
capture technology,” Front Behav. Neurosci., vol. 5, no. 27, pp. 1-6, June
2011.
[18] P. M. Knutsen, D. Derdikman, and E. Ahissar, “Tracking whisker and
head movements in unrestrained behaving rodents,” Journal of
neurophysiology, vol. 93, no. 4, pp. 2294-2301, April 2005.
[19] G. Gyory, et al., “An algorithm for automatic tracking of rat whiskers
(Published Conference Proceedings style),” in Proc. International
Workshop on Visual Observation and Analysis of Animal and Insect
Behavior (VAIB), in conjunction with ICPR, Istanbul, 2010, pp.1-4.
[20] I. Perkson, A. Kosir, P. M. Itskov, J. Tasic, and M. E. Diamondg,
“Unsupervised quantification of whisking and head movement in freely
moving rodents,” Journal of Neurophysiology, vol. 105, no. 4,
pp.1950-1962, April 2011.
[21] J. Voigts, B. Sakmann, T. Celikel, “Unsupervised Whisker Tracking in
Unrestrained Behaving Animals,” Journal of Neurophysiology, vol. 100,
no. 1, pp.504-515, July 2008.
[22] N. Otsu, “A threshold selection method from gray-level histograms,”
IEEE Transactions on Systems, Man, and Cybernetics, vol. 9, no. 1, pp.
62-66, Jan. 1975.
[23] T. Shi, G. Ling, and Y. Yan, “Tracing Vocal-fold Vibrations Using
Level-set Segmentation Method. (Published Conference Proceedings
style),” in Proc. 3rd International Conference on Computational and
Mathematical Biomedical Engineering, Hong Kong, 2013, pp. 63-66.
[24] R. O. Duda, and P. E. Hart, “Use of the Hough transformation to detect
lines and curves in pictures.” Communications of the ACM, vol. 15, no. 1
pp. 11-15, Jan. 1972.
@article{"International Journal of Biological, Life and Agricultural Sciences:70063", author = "Hyun June Kim and Tailong Shi and Seden Akdagli and Sam Most and Yuling Yan", title = "Semi-Automated Tracking of Vibrissal Movements in Free-Moving Rodents Captured by High-Speed Videos", abstract = "Quantitative analyses of whisker movements provide a
means to study functional recovery and regeneration of mouse facial
nerve after an injury. However, accurate tracking of the mouse whisker
movement is challenging. Most methods for whisker tracking require
manual intervention, e.g. fixing the head of the mouse during a study.
Here we describe a semi-automated image processing method, which
is applied to high-speed video recordings of free-moving mice to track
the whisker movements. We first track the head movement of a mouse
by delineating the lower head contour frame-by-frame that allows for
detection of the location and orientation of the head. Then, a region of
interest is identified for each frame; the subsequent application of a
mask and the Hough transform detects the selected whiskers on each
side of the head. Our approach is used to examine the functional
recovery of damaged facial nerves in mice over a course of 21 days.", keywords = "Mystacial macrovibrissae, whisker tracking, head
tracking, facial nerve recovery.", volume = "9", number = "5", pages = "565-5", }
