Neural Mechanisms Underlying Manual Cervical Traction

REFERENCES

• Farrell, J.P. and G.M. Jensen, Manual Therapy: A Critical Assessment of Role in the Profession of Physical Therapy. Physical Therapy, 1992. 72(12):843–852.
   Google Scholar
• Zylbergold, R.S. and M.C. Piper, Cervical Spine Disorders: A Comparison of Three Types of Traction. Spine, 1985. 10(10): 867–871.
   Google Scholar
• Kaltenborn, F., Manual Mobilisation of the Extremity Joints. 1989, Oslo: Olaf Norlis Bokhandel.
   Google Scholar
• Grieve, G., Neck Traction. Physiotherapy, 1982. 68(8):260–265.
   Google Scholar
• Hurwitz, E.L., et al., Manipulation and Mobilisation of the Cervical Spine: A systematic review of the literature. Spine, 1996. 21(15):746–1760.
   Google Scholar
• Koes, B.W. The Efficacy of Physiotherapy For Patients with Neck Pain. in Focusing Ahead, MPAA. 1997. Melbourne, Australia: Manipulative Physiotherapists Association of Australia.
   Google Scholar
• Wall, P.D., Treatment of Pain, in Moving in on Pain, M.O. Shacklock, Editor. 1995, Butterworth-Heinemann: Australia, 64.
   Google Scholar
• Vujnovich, A.L., Neural Plasticity, Muscle Spasm and Tissue Manipulation: A Review of the Literature. Journal of Manual and Manipulative Therapy, 1995. 3(4):152–156.
   Google Scholar
• Zusman, M., Central Nervous System Contribution to Mechanically Produced Motor and Sensory Responses. The Australian Journal of Physiotherapy, 1992. 355:75–77.
   Google Scholar
• Murphy, B.A., N.J. Dawson, and J.R. Slack, Sacroiliac Joint Manipulation Decreases the H-Reflex. Electromyogr. clin. Neurophysiol, 1995. 35:87–94.
   Google Scholar
• Katavich, L., The Effects of Cervical Joint Mobilisation on AlphaMotoneuron ExcitabilityiUnpublished Thesis in School of Physiotherapy, Faculty of Health Studies. 1998, Auckland Institute of Technology: Auckland.
   Google Scholar
• Binder, M.D., C.J. Heckman, and R.K. Powers, How Different Afferent Inputs Control Motoneuron Discharge and the Output of the Motoneuron Pool. Current Opinion in Neurobiology, 1993. 3: 1028–1034.
   Google Scholar
• Kernell, D., Functional Properties of the Neuromuscular System and Force Gradation, in Spasticity: Mechanisms and Management, A.F. Thilmann, D.J. Burke, and W.Z. Rymer, Editors. 1993, SpringerVerlag: Berlin. Heidleberg.
   Google Scholar
• Kernell, D. and H. Hultborn, Synaptic Effects on Recruitment Gain: A Mechanism of Importance for the Input-Output Relations of Motoneuron Pools? Brain Research, 1990. 507:176–179.
   Google Scholar
• Nielson, J. and H. Hultborn, Regulated Properties of Motoneurons and Primary Afferents: New Aspects on Possible Spinal Mechanisms Underlying Spasticity, in Spasticity: Mechanisms and Management, A.F. Thilmann, D.J. Burke, and W.Z. Rymer, Editors. 1993, Springer-Verlag: Berlin. Heidleberg.
   Google Scholar
• Lundberg, A., K. Malmgren, and E.D. Schomburg, Cutaneous Facilitation of Transmission in Reflex Pathways in Ib Afferents to Motoneurons. Journal of Physiology, 1977. 265:763–780.
   Google Scholar
• Kanda, K. and J.E. Desmedt, Cutaneous Facilitation of Large Motor Units and Motor Control of Human Fingers in Precision Grip, in Motor Control Mechanisms in Health and Disease, J. Desmedt, Editor. 1983, Raven Press: New York.
   Google Scholar
• Garnett, R. and J.A. Stephens, The Reflex Responses of Single Motor Units in Human First Dorsal Interosseous Muscle Following Cutaneous Afferent Stimulation. Journal of Physiology, 1980. 303: 351–364.
   Google Scholar
• Garnett, R. and J.A. Stephens, Changes in the Recruitment Threshold of Motor Units Produced by Cutaneous Stimulation in Man. Journal of Physiology, 1981. 311:463–473.
   Google Scholar
• Nielsen, J. and Y. Kagamihara, Differential Projection of the Sural Nerve to Early and Late Recruited Human Tibialis Anterior Motor Units: Change of Recruitment Gain. Acta Physiological Scandanavia, 1993. 147:385–401.
   Google Scholar
• Taylor, M., T. Suvinen, and P. Reade, The Effect of Grade IV Distraction Mobilisation on Patients with Temporomandibular Pain- Dysfunction Disorder. Physiotherapy Theory and Practice, 1994. 10:129–136.
   Google Scholar
• Thabe, H., Electromyography as a Tool to Document Diagnostic Findings and Therapeutic Results Associated with Somatic Dysfunctions in the Upper Cervical Spinal Joints and Sacroiliac Joints. Manual Medicine, 1986. 2:53–58.
   Google Scholar
• Burgess, P.R. and F. Clarke, Characteristics of Knee Joint Receptors in the Cat. Journal of Physiology, 1969. 203:317–335.
   Google Scholar
• Clarke, F.J., Information Signalled by Sensory Fibres in Medial Articular Nerve. Journal of Neurophysiology, 1975. 38:1339–1345.
   Google Scholar
• Grigg, P. and B.J. Greenspan, Response of Primate Joint Afferent Neurons to Mechanical Stimulation of the Knee Joint. Journal of Neurophysiology, 1977. 40:1–8.
   Google Scholar
• Burke, D., S.C. Gandevia, and G. Macefield, Responses to Passive Movement of Receptors in Joint, Skin and Muscle of the Human Hand. Journal of Physiology (London), 1988. 402:347–361.
   Google Scholar
• Lundberg, A., K. Malmgren, and E.D. Schomburg, Role of Joint Afferents in Motor Control Exemplified by Effects on Reflex Pathways from Ib Afferents. Journal of Physiology, 1978. 284: 327–343.
   Google Scholar
• Zusman, M., The Meaning of Mechanically Produced Responses. Australian Journal of Physiotherapy, 1994a. 40(1):35–39.
   Google Scholar
• Baxendale, R.H. and W.R. Ferrell, The Effect of Knee Joint Afferent Discharge on Transmission in Flexion Reflex Pathways in Decerebrate Cats. Journal of Physiology, 1981. 315:231–242.
   Google Scholar
• Baxendale, R.H. and W.R. Ferrell, The Effect of Elbow Joint Afferent Discharge on Transmission in Forelimb Flexion Reflex Pathways to Biceps and Triceps Brachii in Decerebrate Cats. Brain Research, 1982. 247:57–63.
   Google Scholar
• Ferrell, W.R., et al., Fourier Analysis of the Relation Between the Discharge of Quadriceps Motor Units and Periodic Mechanical Stimulation of Cat Knee Joint Receptors. Experimental Physiology, 1990. 75:739–750.
   Google Scholar
• McLain, R.F., Mechanoreceptor Endings in Human Cervical Facet Joints. Spine, 1993. 19(5): 495–501.
   Google Scholar
• Harris, P.H., Cervical Traction: Review of Literature and Treatment Guidelines. Physical Therapy, 1977. 57(8):910–914.
   Google Scholar
• Ferrell, W.R., S.C. Gandevia, and D.I. McCloskey, The Role of Joint Receptors in Human Kinaesthesia when Intramuscular Receptors Cannot Contribute. Journal of Physiology, 1987. 386: 63–71.
   Google Scholar
• Sabbahi, M.A., A.M. Fox, and C. Druffle, Do Joint Receptors Modulate the Motoneuron Excitability? Electromyographic and Clinical Neurophysiology, 1990. 30:387–396.
   Google Scholar
• Gandevia, S.C., et al., Proprioceptive Sensation at the Terminal Joint of the Middle Finger. Journal of Physiology, 1983. 335: 507–517.
   Google Scholar
• Porterfield, J.A. and C. DeRosa, Mechanical Neck Pain: Perspectives in Functional Anatomy. 1995, Philadelphia: WB Saunders Co.
   Google Scholar
• Hunt, C., Mammalian Muscle Spindle: Peripheral Mechanisms. Physiological Reviews, 1990. 70: 643–663.
   Google Scholar
• Lundberg, A., K. Malmgren, and E.D. Schomburg, Reflex Pathways from Group IIMuscle Afferents. 2. Functional Characteristics of Reflex Pathways to Alpha Motoneurons. Experimental Brain Research, 1987. 65:282–293.
   Google Scholar
• Kirkwood, P.A. and T.A. Sears, Monosynaptic Excitation of Motoneurons from Secondary Endings of Muscle Spindles. Nature, 1974. 252(November 15):243–244.
   Google Scholar
• Lundberg, A., K. Malmgren, and E.D. Schomburg, Reflex Pathways from Group II Muscle Afferents. 1. Distribution and Linkage of Reflex Actions to Alpha Motoneurons. Experimental Brain Research, 1987. 65:271–281.
   Google Scholar
• Lundberg, A., K. Malmgren, and E.D. Schomburg, Reflex Pathways from Group IIMuscle Afferents. 3. Secondary Spindle Afferents and the FRA: A New Hypothesis. Experimental Brain Research, 1987. 65:294–306.
   Google Scholar
• Rudomin, P., Presynaptic Inhibition of Muscle Spindle and Tendon Organ Afferents in the Mammalian Spinal Cord. Trends in Neuroscience, 1990. 13(12):499–505.
   Google Scholar
• Faist, M., V. Dietz, and E. Pierrot-Deseilligny, Modulation, Probably Presynaptic in Origin, of Monosynaptic Ia Excitation During Human Gait. Experimental Brain Research, 1996. 109(3): 441–9.
   Google Scholar
• Berardelli, A., et al., Evidence Favouring Presynaptic Inhibition Between Antagonist Muscle Afferents in the Human Forearm. Journal of Physiology, 1987. 391:71–83.
   Google Scholar
• Hultborn, H., et al., Changes in Presynaptic Inhibition of Ia Fibres at the Onset of Voluntary Contraction in Man. Journal of Physiology, 1987. 389:757–772.
   Google Scholar
• Misiaszek, J.E., et al., Long-lasting Inhibition of the Human Soleus H-reflex Pathway after Passive Movement. Brain Research, 1995. 677:69–81.
   Google Scholar
• Harrison, P.J. and E. Jankowska, Sources of Input to Interneurones Mediating Group I Non-Reciprocal Inhibition of Motoneurons in the Cat. Journal of Physiology, 1985. 361:379–401.
   Google Scholar
• Fetz, E.E., et al., Autogenic Inhibition of Motoneurons by Impulses in Group Ia Muscle Spindle Afferents. Journal of Physiology, 1979. 293:173–195.
   Google Scholar
• Moore, J.C., The Golgi Tendon Organ: A Review and Update. The American Journal of Occupational Therapy, 1984. 38(4):227–236.
   Google Scholar
• Edin, B.B. and J.H. Abbs, Finger Movement Responses of Cutaneous Mechanoreceptors in the Dorsal Skin of the Human Hand. J Neurophysiol, 1991. 65(3):657–70.
   Google Scholar
• Edin, B.B., Quantitative Analysis of Static Strain Sensitivity in Human Mechanoreceptors from Hairy Skin. J Neurophysiol, 1992. 67(5):105–13.
   Google Scholar
• Grigg, P., Stretch Sensitivity of Mechanoreceptor Neurons in Rat Hairy Skin. J Neurophysiol, 1996. 76(5):2886–95.
   Google Scholar
• Walk, D. and M.A. Fisher, Effects of Cutaneous Stimulation on Ipislateral and Contralateral Motoneuron Excitability: An Analysis Using H-reflexes and F-waves. Electromyography and Clinical Neurophysiology, 1993. 33:59–264.
   Google Scholar
• Nakashima, K., et al., Cutaneous Effects of Presynaptic Inhibition of Flexor Ia Afferents in the Human Forearm. Journal of Physiology, 1990. 426:369–380.
   Google Scholar
• Iles, J.F., Evidence for Cutaneous and Corticospinal Modulation of Presynaptic Inhibition of Ia afferents from the Human Lower Limb. Journal of Ph;ysiology, 1996. 491:197–207.
   Google Scholar
• Sabbahi, M.A. and E.M. Sedgwick, H-reflex Modulation by Natural Stimulation of the Skin. Electroencephalography and Clinical Neurophysiology, 1976. 41:537.
   Google Scholar
• Marque, P., E. Perrot-Deseilligny, and M. Simonetta-Morequ, Evidence for Excitation of the Human Lower Limb Motoneurons by Group II Muscle Afferents. Experimental Brain Research, 1996. 109: 357–360.
   Google Scholar
• Robinson, K.L., A.J. McComas, and A.Y. Belanger, Control of Soleus Motoneuron Excitability During Muscle Stretch in Man. Journal of Neurology, Neurosurgery and Psychiatry, 1982. 45:699–704.
   Google Scholar
• Harms, A.D. and K.B. Castine. An Examination of the Differential Blockade of Cutaneous Nerve Using EMLATM Cream: A Pilot Study in Normal Subjects. in MPAA Tenth Biennial Conference. 1997. Melbourne: MPAA.
   Google Scholar
• Behrends, T., E.D. Schomburg, and H. Steffens, Group II Muscle Afferents and Low Threshold Mechanoreceptive Skin Afferents Converging onto Interneurons in a Common Reflex Pathway to Alpha Motoneurons. Brain Research, 1983. 265:125–128.
   Google Scholar
• Schieppati, M. and A. Nardone, Medium-latency Stretch Reflexes of Foot and Leg Muscles Analysed by Cooling the Lower Limb in Standing Humans. Journal of Physiology, 1997. 503(3): 691–698.
   Google Scholar
• Cavallari, P., et al., Cutaneous Facilitation of Transmission in Ib Reflex Pathways in the Human Upper Limb. Experimental Brain Research, 1985. 60:197–199.
   Google Scholar
• Pierrot-Deseilligny, E., et al., Cutaneous Depression of Ib Reflex Pathways to Motoneurons in Man. Experimental Brain Research, 1981. 42:351–361.
   Google Scholar
• Pierrot-Deseilligny, E., C. Bergego, and R. Katz, Reversal in Cutaneous Control of Ib Pathways During Human Voluntary Contraction. Brain Research, 1982. 233:400–403.
   Google Scholar