Skip to main content
Key Specialties
Cardiology Diabetology Endocrinology Gastroenterology Geriatrics and Gerontology Gynecology and Obstetrics Hematology Infectious Disease Internal Medicine Nephrology Neurology Oncology Pediatrics Respiratory Medicine Rheumatology Surgery
Congress Coverage
2024 ACC Congress 2023 ESMO Congress 2023 EASD Congress 2023 ERS Congress 2023 ESC Congress
Clinical Collections
Advances in Alzheimer’s

Keynote webinar | Spotlight on medication adherence

LIVE: Thursday 27th June 2024, 18:00-19:30 (CEST)
Join our expert panel to discover why you need to understand the drivers of non-adherence in your patients, and how you can optimize medication adherence in your clinics to drastically improve patient outcomes.
ADVANCED SEARCH
Log in
Top
Experimental Brain Research
Published in: Experimental Brain Research 2/2012

01-08-2012 | Research Article

Proprioceptive reaction times and long-latency reflexes in humans

Authors: C. D. Manning, S. A. Tolhurst, P. Bawa

Published in: Experimental Brain Research | Issue 2/2012

Login to get access

Abstract

The stretch of upper limb muscles results in two electromyographic (EMG) peaks, M1 and M2. The amplitude of M2 peak can generally be modified by giving prior instruction to the subject on how to react to the applied perturbation. The unresolved question is whether the amplitude modulation results from change in the gain of the reflex pathway contributing to M2, or by superposition of reaction time (RT) activity. The following study attempted to resolve this question by examining the overlap between proprioceptive RT and M2 activities. Subject’s right wrist flexors were stretched, and he/she was instructed either (1) not to intervene (passive task) or (2) to react as fast as possible by simultaneously flexing both wrists (active or compensate task). Under passive and active conditions, M1 and M2 were observed from EMG of right wrist flexors, and during the active condition, RT activities were additionally observed from both sides. The onset and offset of M2 (M1onset, M2offset) were measured from the passive averages, while the RT was measured from the averaged EMG response of the left wrist flexors. For between-subject correlations, the data were divided into two sets: (1) subjects with RT shorter than M2offset (fast group) and (2) subjects with RT more than 10 ms longer than their M2offset (slow group). Modulation during M2 period was large for the fast group, and it was almost zero for the slow group. These results indicate that the superimposition of RT activity mainly contributes to the instruction-dependent modulation of M2 peak.
Literature
Akazawa K, Milner TE, Stein RB (1983) Modulation of reflex EMG and stiffness in response to stretch of human finger muscles. J Neurophysiol 49:16–27PubMed
Bawa P, Manning CD (2011) Gain modulation of longer latency stretch reflex. Soc Neurosci Abstracts 810.17/QQ21
Calancie B, Bawa P (1985a) Firing patterns of human flexor carpi radialis motor units during the stretch reflex. J Neurophysiol 53:1179–1193PubMed
Calancie B, Bawa P (1985b) Voluntary and reflexive recruitment of flexor carpi radialis motor units in humans. J Neurophysiol 53:1194–1200PubMed
Capaday C, Forget R, Milner T (1994) A re-examination of the effects of instruction on the long-latency stretch reflex response of the flexor pollicis longus muscle. Exp Brain Res 100:515–521PubMedCrossRef
Carlsen AN, Chua R, Inglis JT, Sanderson DJ, Franks IM (2004) Can prepared responses be stored subcortically? Exp Brain Res 159:301–309PubMedCrossRef
Carr LJ, Harrison LM, Stephens JA (1994) Evidence for the bilateral innervation of certain homologous motoneurone pools in man. J Physiol 475:217–227PubMed
Cheney PD, Fetz EE (1984) Corticomotoneuronal cells contribute to long-latency stretch reflexes in the rhesus monkey. J Physiol (Lond) 349:249–272
Chernikoff R, Taylor FV (1952) Reaction time to kinesthetic stimulation resulting from sudden arm displacement. J Exp Psychol 43:1–8PubMedCrossRef
Colburn TR, Evarts EV (1978) Use of brushless DC torque motors in studies of neuromuscular function. In: Desmedt JE (ed) Cerebral motor control in man: Long loop mechanisms, vol 4. Prog Clin Neurophysiol. Karger, Basel, pp 153–166
Colebatch JG, Gandevia SC, McCloskey DI, Potter EK (1979) Subject instruction and long latency reflex responses to muscle stretch. J Physiol 292:527–534PubMed
Conrad B, Meyer-Lohmann J, Matsunami K, Brooks VB (1975) Precentral unit activity following torque pulse injections into elbow movements. Brain Res 94:219–236PubMedCrossRef
Crago PE, Houk JC, Hasan Z (1976) Regulatory action of human stretch reflex. J Neurophysiol 39:925–935PubMed
Day BL, Rothwell JC, Marsden CD (1983) Interaction between the long-latency stretch reflex and voluntary electromyographic activity prior to a rapid voluntary motor reaction. Brain Res 270:55–62PubMedCrossRef
Day BL, Rothwell JC, Thompson PD, Maertens De Noordhout A, Nakashima K, Shannon K, Marsden CD (1989) Delay in the execution of voluntary movement by electrical or magnetic brain stimulation in intact man. Brain 112:649–663PubMedCrossRef
Deuschl G, Schenck E, Lücking CH (1985) Long-latency responses in human thenar muscles mediated by fast conducting muscle and cutaneous afferents. Neurosc Lett 55:361–366CrossRef
Dimitriou M, Franklin DW, Wolpert DM (2012) Task-dependent coordination of rapid bimanual motor responses. J Neurophysiol 107:890–901PubMedCrossRef
Doemges F, Rack PM (1992) Task-dependent changes in the response of human wrist joints to mechanical disturbance. J Physiol 447:575–585PubMed
Evarts EV, Granit R (1976) Relation of reflexes and intended movements. Prog Brain Res 4:1–14CrossRef
Evarts EV, Tanji J (1976) Reflex and intended responses in motor cortex pyramidal tract neurons of monkey. J Neurophysiol 39:1069–1080PubMed
Evarts EV, Teräväinen H, Calne DB (1981) Reaction time in Parkinson’s disease. Brain 104:167–186PubMedCrossRef
Fitts PM (1954) The information capacity of the human motor system in controlling the amplitude of movement. J Exp Psych 47:381–391CrossRef
Flanders M, Cordo PJ, Anson JG (1986) Interaction between visually and kinesthetically triggered voluntary responses. J Motor Behav 18:427–448
Gerilovsky L, Reischer H, Struppler A (1987) Long-latency stretch responses in man—Segmental versus suprasegmental hypothesis. In: Struppler A, Weindl A (eds) Advances in applied neurological sciences, Pt IV. Clinical aspects of sensory motor integration. Springer, Berlin, pp 176–188
Hammond PH (1955) Involuntary activity in biceps following the sudden application of velocity to the abducted forearm. J Physiol 127:23P–25P
Hammond PH (1956) The influence of prior instruction to the subject on an apparently involuntary neuro-muscular response. J Physiol 132:17P–18P
Hammond PH (1960) An experimental study of servo action in human muscular control. Proc III International Conf Med Electron, pp 190–199
Heckman RL, Honeycutt CF, Ravichandran VJ, Perreault EJ (2011) Influence of perturbation intensity on the rapid release of triggered reactions. Soc Neurosc Abstracts 910.18
Houk JC (1978) Participation of reflex mechanisms and reaction-time processes in the compensatory adjustments to mechanical disturbances. In: Desmedt JE (ed) Cerebral motor control in man: long Loop mechanisms, vol 4. Progress Clin Neurophysiol. Karger, Basel, pp 193–215
Jaeger RJ, Gottlieb GL, Agarwal GC (1982) Myoelectric responses at flexors and extensors of human wrist to step torque perturbations. J Neurophysiol 48:388–402PubMed
Kaluzny P, Palmeri A, Wiesendanger M (1994) The problem of bimanual coupling: a reaction time study of simple unimanual and bimanual finger responses. EEG Clin Neurophysiol 93:450–458CrossRef
Kimura T, Haggard P, Gomi H (2006) Transcranial magnetic stimulation over sensorimotor cortex disrupts anticipatory reflex gain modulation for skilled action. J Neurosc 26:9272–9281CrossRef
Lacquaniti F, Borghese NA, Carrozzo M (1991) Transient reversal of the stretch reflex in human arm muscles. J Neurophysiol 66:939–954PubMed
Lee RG, Tatton WG (1975) Motor responses to sudden limb displacements in primates with specific CNS lesions and in humans patients with motor system disorders. Can J Neurol Sci 2:285–293PubMed
Lee RG, Tatton WG (1978) Long loop reflexes in man: Clinical applications. In: Desmedt JE (ed) Cerebral motor control in man: long loop mechanisms, vol 4. Progress in Clinical Neurophysiol. Karger, Basel, pp 320–333
Lewis GN, MacKinnon CD, Perreault EJ (2006) The effect of instruction on the excitability of spinal and supraspinal reflex pathways projecting to the biceps muscle. Exp Brain Res 174:413–425PubMedCrossRef
Loo CKC, McCloskey DI (1985) Effects of prior instruction and anaesthesia on long-latency responses to stretch in the long flexor of the human thumb. J Physiol 365:285–296PubMed
MacKinnon CD, Verrier MC, Tatton WG (2000) Motor cortical potentials precede long-latency EMG activity evoked by imposed displacements of the human wrist. Exp Brain Res 131:477–490PubMedCrossRef
Manning CD, Bawa P (2011) Heteronymous reflex connections in human upper limb muscles in response to stretch of forearm muscles. J Neurophysiol 106:1489–1499PubMedCrossRef
Manning CD, Tolhurst SA, Bawa P (2012) Gain modulation of long latency reflex in humans. ISEK Abstr
Marsden CD, Merton PA, Morton HB (1976) Stretch reflex and servo action in a variety of human muscles. J Physiol 259:531–560PubMed
Matthews PBC, Farmer SF, Ingram DA (1990) On the localization of the stretch reflex of intrinsic hand muscles in a patient with mirror movements. J Physiol (Lond) 428:561–577
Melvill-Jones G, Watt DGD (1971) Observations on the control of stepping and hopping movements in man. J Physiol 219:709–727
Mutha PK, Sainburg RL (2009) Shared bimanual tasks elicit bimanual reflexes during movement. J Neurophysiol 102:3142–3155PubMedCrossRef
Nakazawa K, Yamamoto SI, Yano HI (1997) Short- and long-latency reflex responses during different motor tasks in elbow flexor muscles. Exp Brain Res 116:20–28PubMedCrossRef
Palmer E, Ashby P (1992) Evidence that a long latency stretch reflex in humans is transcortical. J Physiol (Lond) 449:429–440
Perreault EJ, Chen K, Trumbower RD, Lewis G (2008) Interaction with compliant loads alter stretch reflex gains but not intramuscular coordination. J Neurophysiol 99:2101–2113PubMedCrossRef
Pruszynski JA, Scott SH (2012) Optimal feedback control and the long-latency stretch reflex response. Exp Brain Res 218:341–359PubMedCrossRef
Pruszynski JA, Kurtzer I, Scott SH (2008) Rapid responses are appropriately tuned to the metrics of a visuospatial task. J Neurophysiol 100:224–238PubMedCrossRef
Pruszynski JA, Kurtzer I, Scott SH (2011) The long latency reflex is composed of at least two functionally independent processes. J Neurophysiol 106:449–459PubMedCrossRef
Rothwell JC (1990) Long latency reflexes of human arm muscles in health and disease. In: Rossini PM, Mauguiere F (eds) New trends and advanced techniques in clinical neurophysiology. EEG Suppl 41. Elsevier, pp 251–263
Rothwell JC, Traub MM, Marsden CD (1980) Influence of intent on human long-latency stretch reflex. Nature 286:496–498PubMedCrossRef
Schluter ND, Krams M, Rushworth MFS, Passingham RE (2001) Cerebral dominance for action in the human brain: the selection of actions. Neuropsychologia 39:105–113PubMedCrossRef
Selen LPJ, Shalden MN, Wolpert DM (2012) Deliberation in the motor system: reflex gains tract evolving evidence leading to a decision. J Neurosc 32:2276–2286CrossRef
Shemmell J, An JH, Perreault EJ (2009) The differential role of motor cortex on stretch reflex modulation induced by changes in environmental mechanics and verbal instruction. J Neurosci 29:13255–13263PubMedCrossRef
Soechting JF, Lacquaniti F (1988) Quantitative evaluation of the electromyographic responses to multidirectional load perturbations of the human arm. J Neurophysiol 59:1296–1313PubMed
Spirduso WW, Lee WA, Baylor AM (1980) Initiation of bilateral responses in a kinesthetic reaction time task. J Motor Behav 12:173–184
Tatton WG, Lee RG (1975) Evidence for abnormal long-loop reflexes in rigid Parkinsonian patients. Brain Res 100:671–676PubMedCrossRef
Tatton WG, Bawa P, Bruce IC, Lee RG (1978) Long loop reflexes in monkeys: an interpretative base for human reflexes. In: Desmedt JE (ed) Cerebral motor control in man: long loop mechanisms, vol 4. Prog Clin Neurophysiol. Karger, Basel, pp 229–245
Tatton WG, Bawa P, Bruce IC (1979) Altered motor cortical activity in extrapyramidal rigidity. In: Poirier LJ, Sourkes TL, Bédard PJ (eds) Advances in neurology, vol 24. Raven Press, New York, pp 141–160
Zhang Z, Francisco EM, Holden JK, Dennis RG, Tommerdahl M (2011) Somatosensory information processing in the aging population. Frontiers Aging Neurosci 3:1–9
Metadata
Title
Proprioceptive reaction times and long-latency reflexes in humans
Authors
C. D. Manning
S. A. Tolhurst
P. Bawa
Publication date
01-08-2012
Publisher
Springer-Verlag
Published in
Experimental Brain Research / Issue 2/2012
Print ISSN: 0014-4819
Electronic ISSN: 1432-1106
DOI
https://doi.org/10.1007/s00221-012-3157-x

Other articles of this Issue 2/2012

Experimental Brain Research 2/2012 Go to the issue

Research Article

Perceptual learning in temporal discrimination: asymmetric cross-modal transfer from audition to vision

Research Article

Oral hapsis guides accurate hand preshaping for grasping food targets in the mouth

Research Article

Facilitating masked visual target identification with auditory oddball stimuli

Research Article

Prefrontal electroencephalographic activity during the working memory processes involved in a sexually motivated task in male rats

Research Article

Training-induced modifications of corticospinal reactivity in severely affected stroke survivors

Research Article

Ankle joint movements are encoded by both cutaneous and muscle afferents in humans