Abstract
Whiskers are present on most mammals, and whisker specialists, such as rodents, pinnipeds and insectivores, can actively position their whiskers to efficiently guide navigation, locomotion and exploration. That only a small number of whiskers give enough information about the local environment to be the primary tactile sense in many mammals has prompted researchers to explore how well adapted the whisker system is and how “matched” these sensors are to their function. In this chapter, we suggest that whisker touch systems have a matched filter design by arguing that (i) the layout of the vibrissae and their mechanical properties provide a computationally cheap way to gather tactile and spatial information; (ii) this layout is topographically mapped throughout the brain, enabling temporal and spatial information to be preserved easily during processing, freeing up other areas of the brain; and (iii) movement of the whiskers can focus the sensors onto salient regions of space and also control the amount, type and quality of information gathered from an environment. That anatomical and behavioural characteristics are maintained throughout many different mammalian orders indicates the importance of vibrissal touch sensing in arboreal, nocturnal animals, hence its conservation throughout mammalian evolution.
Keywords
- Superior Colliculus
- Central Pattern Generator
- Intrinsic Muscle
- Active Touch
- Extrinsic Muscle
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.
This is a preview of subscription content, access via your institution.
Buying options
Tax calculation will be finalised at checkout
Purchases are for personal use only
Learn about institutional subscriptionsReferences
Ahl AS (1986) The role of vibrissae in behavior – a status review. Vet Res Commun 10:245–268
Anjum F, Turni H, Mulder PG, van der Burg J, Brecht M (2006) Tactile guidance of prey capture in Etruscan shrews. Proc Natl Acad Sci U S A 103:16544–16549
Arkley K, Grant RA, Mitchinson B, Prescott TJ (2014) Strategy change in vibrissal active sensing during rat locomotion. Curr Biol 24(13):1507–1512
Barnett SA (2007) The rat: a study in behaviour. Aldine Transaction, London
Baumann KI, Chan E, Halata Z, Senok SS, Yung WH (1996) An isolated rat vibrissal preparation with stable responses of slowly adapting mechanoreceptors. Neurosci Lett 213:1–4
Benedetti F (1991) The postnatal emergence of a functional somatosensory representation in the superior colliculus of the mouse. Dev Brain Res 60(1):51–57
Berg RW, Kleinfeld D (2003a) Rhythmic whisking by rat: retraction as well as protraction of the vibrissae is under active muscular control. J Neurophysiol 89:104–117
Berg RW, Kleinfeld D (2003b) Vibrissa movement elicited by rhythmic electrical microstimulation to motor cortex in the aroused rat mimics exploratory whisking. J Neurophysiol 90:2950–2963
Birdwell JA, Solomon JH, Thajchayapong M, Taylor MA, Cheely M, Towal RB, Conradt J, Hartmann MJZ (2007) Biomechanical models for radial distance determination by the rat vibrissal system. J Neurophysiol 98:2439–2455
Brecht M, Preilowski B, Merzenich MM (1997) Functional architecture of the mystacial vibrissae. Behav Brain Res 84(1–2):81–97
Bugbee NM, Eichelman BS (1972) Sensory alterations and aggressive behaviour in the rat. Physiol Behav 8:981–985
Cao Y, Roy S, Sachdev RN, Heck DH (2012) Dynamic correlation between whisking and breathing rhythms in mice. J Neurosci 32:1653–1659
Carlson AJ, Hoelzel F (1949) Influence of texture of food on its acceptance by rats. Science 109:63–64
Carvell GE, Simons DJ (1990) Biometric analyses of vibrissal tactile discrimination in the rat. J Neurosci 10(8):2638–2648
Christie D, Terry P, Oakley DA (1990) The effect of unilateral anteromedial cortex lesions on prey-catching and spatio-motor behaviour in the rat. Behav Brain Res 37:263–268
Cramer NP, Keller A (2006) Cortical control of a whisking central pattern generator. J Neurophysiol 96:209–217
Cramer N, Li Y, Keller A (2007) The whisking rhythm generator: a novel mammalian network for the generation of movement. J Neurophysiol 97(3):2148–2158
Czech-Damal NU, Liebschner A, Miersch L, Klauer G, Hanke FD, Marshall C, Dehnhardt G, Hanke W (2011) Electroreception in the Guiana dolphin (Sotalia guianensis). Proc R Soc B 279(1729):663–668
Dehnhardt G (1994) Tactile size discrimination by a California sea lion (Zalophus californianus) using its mystacial vibrissae. J Comp Physiol A 175:791–800
Dehnhardt G, Dücker G (1996) Tactual discrimination of size and shape by a California sea lion (Zalophus californianus). Anim Learn Behav 24(4):366–374
Dehnhardt G, Kaminski A (1995) Sensitivity of the mystacial vibrissae of harbor seals (phoca- vitulina) for size differences of actively touched objects. J Exp Biol 198:2317
Dehnhardt G, Mauck B, Bleckmann H (1998) Seal whiskers detect water movements. Nature 394(6690):235–236
Dehnhardt G, Mauck B (2008) Mechanoreception in secondarily aquatic vertebrates. In: Thewissen JGM, Nummela S (eds) Sensory evolution on the threshold–adaptations in secondarily aquatic vertebrates. University of California Press, Berkely, pp 295–314
Dehnhardt G, Mauck B, Hanke W, Bleckmann H (2001) Hydrodynamic trail-following in harbor seals (Phoca vitulina). Science 293:102–104
Deschenes M, Timofeeva E, Lavallee P (2003) The relay of high-frequency sensory signals in the Whisker-to-barreloid pathway. J Neurosci 23:6778–6787
Deschênes M, Moore J, Kleinfeld D (2012) Sniffing and whisking in rodents. Curr Opin Neurobiol 22(2):243–250
Diamond ME, Petersen RS, Harris JA, Panzeri S (2003) Investigations into the organization of information in sensory cortex. J Physiol Paris 97:529–536
Diamond ME, von Heimendahl M, Knutsen PM, Kleinfeld D, Ahissar E (2008) ‘Where’ and ‘what’ in the whisker sensorimotor system. Nat Rev Neurosci 9:601–612
Dorfl J (1982) The musculature of the mystacial vibrissae of the white-mouse. J Anat 135:147–154
Dräger UC, Hubel DH (1976) Topography of visual and somatosensory projections to mouse superior colliculus. J Neurophysiol 39(1):91–101
Dyck RH (2005) Vibrissae. In: Wishaw IQ, Kolb B (eds) The behavior of the laboratory rat: a handbook with tests. Oxford University Press, Oxford, pp 81–89
Feldman DE, Brecht M (2005) Map plasticity in somatosensory cortex. Science 310(5749):81
Friedman WA, Jones LM, Cramer NP, Kwegyir-Afful EE, Zeigler HP, Keller A (2006). Anticipatory activity of motor cortex in relation to rhythmic whisking. J Neurophysiol, 95(2):1274–1277
Gao P, Bermejo R, Zeigler HP (2001) Whisker deafferentation and rodent whisking patterns: behavioral evidence for a central pattern generator. J Neurosci 21:5374–5380
Glaser N, Wieskotten S, Otter C, Dehnhardt G, Hanke W (2011) Hydrodynamic trial following in a California sea lion (Zalophus Californianus). J Comp Physiol A 197:141–151
Grant R, Mitchinson B, Fox C, Prescott TJ (2009) Active touch sensing in the rat: anticipatory and regulatory control of whisker movements during surface exploration. J Neurophysiol 101:862–874
Grant RA, Sperber A, Prescott TJ (2012) The role of orienting in vibrissal touch sensing. Front Behav Neurosci 6:39
Grant RA, Weiskotten S, Wengst N, Prescott TJ, Dehnhardt G (2013a) Vibrissal touch sensing in the harbour seal (Phoca vitulina): how do seals judge size? J Comp Physiol A 199(6):521–533, In Special Issue on the Sensory Biology of Aquatic Mammals
Grant RA, Haidarliu S, Kennerley NJ, Prescott TJ (2013b) The evolution of active vibrissal sensing in mammals: evidence from vibrissal musculature and function in the marsupial opossum Monodelphis domestica. J Exp Biol 216(18):3483–3494
Grant RA, Sharp PS, Kennerley AJ, Berwick J, Grierson A, Ramesh T, Prescott TJ (2013c) Abnormalities in whisking behaviour are associated with lesions in brain stem nuclei in a mouse model of amyotrophic lateral sclerosis. Behav Brain Res 259:274–283
Grant R, Itskov PM, Towal B, Prescott TJ (eds) (2014) Active touch sensing. Frontiers E-books
Gustafson JW, Felbain-Keramidas SL (1977) Behavioral and neural approaches to the function of the mystacial vibrissae. Psychol Bull 84:477–488
Haidarliu S, Ahissar E (1997) Spatial organization of facial vibrissae and cortical barrels in the guinea pig and golden hamster. J Comp Neurol 385:515–527
Haidarliu S, Ahissar E (2001) Size gradients in the barreloids in the rat thalamus. J Comp Neurol 429:372–387
Haidarliu S, Simony E, Golomb D, Ahissar E (2010) Muscle architecture in the mystacial pad of the rat. Anat Rec 293:1192–1206
Hanke W, Witte M, Miersch L, Brede M, Oeffner J, Michael M, Hanke F, Leder A, Dehnhardt G (2010) Harbor seal vibrissa morphology suppresses vortex-induced vibrations. J Exp Boil 213:2665–2672
Harvey MA, Bermejo R, Zeigler HP (2001) Discriminative whisking in the head-fixed rat: optoelectronic monitoring during tactile detection and discrimination tasks. Somatosens Mot Res 18:211–222
Hemelt ME, Keller A (2007) Superior sensation: superior colliculus participation in rat vibrissa system. BMC Neurosci 8(1):12
Hyvärinen H (1989) Diving in darkness: whiskers as sense organs of the Ringed seal (Phoca hispida). J Zool 238:663–678 system. BMC Neurosci 8:12
Ibrahim L, Wright EA (1975) The growth of rats and mice vibrissae under normal and some abnormal conditions. J Embryol Exp Morphol 33:831–844
Ivanco TL, Pellis SM, Whishaw IQ (1996) Skilled forelimb movements in prey catching and in reaching by rats (Rattus norvegicus) and opossums (Monodelphis domestica): relations to anatomical differences in motor systems. Behav Brain Res 79:163–181
Jenkinson EW, Glickstein M (2000) Whiskers, barrels, and cortical efferent pathways in gap crossing by rats. J Neurophysiol 84:1781–1789
Ji Q, Luo Z-X, Yuan C-X, Wible JR, Zhang J-P, Georgi JA (2002) The earliest known eutherian mammal. Nature 416:816–822
Johansson RS, Vallbo AB (1979) Tactile sensibility in the human hand: relative and absolute densities of four types of mechanoreceptive units in glabrous skin. J Physiol 286:283–300
Knutsen PM, Biess A, Ahissar E (2008) Vibrissal kinematics in 3D: tight coupling of azimuth, elevation, and torsion across different whisking modes. Neuron 59:35–42
Krupa DJ, Brisben AJ, Nicolelis MA (2001) A multi-channel whisker stimulator for producing spatiotemporally complex tactile stimuli. J Neurosci Methods 104:199–208
Luo Z-X, Yuan C-X, Meng Q-J, Ji Q (2011) A Jurassic eutherian mammal and divergence of marsupials and placentals. Nature 476:442–445
Lyne AG (1959) The systematic and adaptive significance of the vibrissae in the Marsupialia. Proc Zool Soc Lond 133:79–133
Maderson PFA (1972) When? Why? And how? Some speculations on the evolution of the vertebrate integument. Am Zool 12:159–171
Maderson PFA (2003) Mammalian skin evolution: a re-evaluation. Exp Dermatol 12:233–236
Mauck B, Eysel U, Dehnhardt G (2000) Selective heating of vibrissal follicles in seals (Phoca vitulina) and dolphins (Sotalia fluviatilis guianensis). J Exp Biol 203(14):2125–2131
Milne AO, Grant RA (2014) Characterisation of whisker control in the California sea lion (Zalophus californianus) during a complex, dynamic sensorimotor task. J Comp Physiol A 200(10):871–879
Mitchinson B, Prescott TJ (2013) Whisker movements reveal spatial attention: a unified computational model of active sensing control in the rat. PLoS Comput Biol 9(9):e1003236
Mitchinson B, Gurney KN, Redgrave P, Melhuish C, Pipe AG, Pearson M, Gilhespy I, Prescott TJ (2004) Empirically inspired simulated electro-mechanical model of the rat mystacial follicle-sinus complex. Proc Biol Sci 271:2509–2516
Mitchinson B, Martin CJ, Grant RA, Prescott TJ (2007) Feedback control in active sensing: rat exploratory whisking is modulated by environmental contact. Proc Biol Sci 274:1035–1041
Mitchinson B, Grant RA, Arkley KP, Perkon I, Prescott TJ (2011) Active vibrissal sensing in rodents and marsupials. Phil Trans B 366(1581):3037–3048
Moore CI, Andermann ML (2005) The vibrissa resonance hypothesis. In: Somatosensory plasticity, Ebner FF (ed) CRC Press, Taylor & Francis, London, pp 21–60
Moore JD, Deschenes M, Furata T, Huber D, Smear MC, Demers M, Kleinfeld D (2013) Hierarchy of orofacial rhythms revealed through whisking and breathing. Nature 497:205–210
Muchlinski MN, Durham EL, Smith TD, Burrows AM (2013) Comparative histomorphology of intrinsic vibrissa musculature among primates: implications for the evolution of sensory ecology and “face touch”. Am J Phys Anthropol 150(2):301–312
Pocock RI (1914) On the facial vibrissae of mammalia. Proc Zool Soc Lond 84:889–912
Prescott TJ, Diamond ME, Wing AM (2011) Active touch sensing. Phil Trans R Soc Lond B: Biol Sci 366(1581):2989–2995
Reep RL, Stoll ML, Marshall CD, Homer BL, Samuelson DA (2001) Microanatomy of facial vibrissae in the Florida manatee: the basis for specialized sensory function and oripulation. Brain Behav Evol 58:1–14
Rice FL, Mance A, Munger BL (1986) A comparative light microscopic analysis of the sensory innervation of the mystacial pad. I. Innervation of the vibrissal follicle-sinus complexes. J Comp Neurol 252:154–174
Rowe TB, Macrini TE, Luo Z-X (2011) Fossil evidence on origin of the mammalian brain. Science 332(6032):955–957
Sachdev RN, Sellien H, Ebner F (2001) Temporal organization of multi-whisker contact in rats. Somatosens Mot Res 18:91–100
Sachdev RNS, Sato T, Ebner FF (2002) Divergent movement of adjacent whiskers. J Neurophysiol 87:1440–1448
Sawyer EK, Liao CC, Qi HX, Balaram P, Matrov D, Kaas JH (2015) Subcortical barrelette-like and barreloid-like structures in the prosimian galago (Otolemur garnetti). Proc Natl Acad Sci 112(22):7079–7084
Shuler MG, Krupa DJ, Nicolelis MA (2001) Integration of bilateral whisker stimuli in rats: role of the whisker barrel cortices. Cereb Cortex 12:86–97
Szwed M, Bagdasarian K, Blumenfeld B, Barak O, Derdikman D, Ahissar E (2006) Responses of trigeminal ganglion neurons to the radial distance of contact during active vibrissal touch. J Neurophysiol 95:791–802
Towal RB, Hartmann MJ (2006) Right-left asymmetries in the whisking behavior of rats anticipate head movements. J Neurosci 26:8838–8846
Vincent SB (1912) The function of the vibrissae in the behaviour of the white rat. Behav Monogr 1:1–82
Vincent SB (1913) The tactile hair of the white rat. J Comp Neurol 23:1–36
Waite PME, Tracey DJ (1995) Trigeminal sensory system. In: Paxinos G (ed) The rat nervous system. Academic, Sydney, pp 705–724
Wallace DJ, Greenberg DS, Sawinski J, Rulla S, Notaro G, Kerr JND (2013) Rats maintain an overhead binocular field at the expense of constant fusion. Nature 498:65–69
Wehner R (1987) ‘Matched filters’ – neural models of the external world. J Comp Physiol A 161:511–531
Welker WI (1964) Analysis of sniffing in the albino rat. Behavior 22:223–224
Wieskotten S, Dehnhardt G, Mauck B, Miersch L, Hanke W (2010a) Hydrodynamic determination of the moving direction of an artificial fin by a harbor seal (Phoca vitulina). J Exp Biol 213:2194–2200
Wieskotten S, Dehnhardt G, Mauck B, Miersch L, Hanke W (2010b) The impact of glide phases on the trackability of hydrodynamic trials in harbor seals (Phoca vitulina). J Exp Biol 213:3734–3740
Wolfe J, Mende C, Brecht M (2011) Social facial touch in rats. Behav Neurosci 125(6):900
Woolsey TA, Van der Loos H (1970) The structural organization of layer IV in the somatosensory region (SI) of the mouse cerebral cortex: the description of a cortical field composed of discrete cytoarchitectonic units. Brain Res 17:205–242
Author information
Authors and Affiliations
Corresponding author
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2016 Springer International Publishing Switzerland
About this chapter
Cite this chapter
Grant, R.A., Arkley, K.P. (2016). Matched Filtering in Active Whisker Touch. In: von der Emde, G., Warrant, E. (eds) The Ecology of Animal Senses. Springer, Cham. https://doi.org/10.1007/978-3-319-25492-0_3
Download citation
DOI: https://doi.org/10.1007/978-3-319-25492-0_3
Published:
Publisher Name: Springer, Cham
Print ISBN: 978-3-319-25490-6
Online ISBN: 978-3-319-25492-0
eBook Packages: Biomedical and Life SciencesBiomedical and Life Sciences (R0)