Dynamic Spatial Tuning of Cervical Muscle Reflexes to Multidirectional Seated Perturbations

Study Design. Human volunteers were exposed experimentally to multidirectional seated perturbations. Objective. To determine the activation patterns, spatial distribution and preferred directions of reflexively activated cervical muscles for human model development and validation. Summary of Background Data. Models of the human head and neck are used to predict occupant kinematics and injuries in motor vehicle collisions. Because of a dearth of relevant experimental data, few models use activation schemes based on in vivo recordings of muscle activation and instead assume uniform activation levels for all muscles within presumed agonist or antagonist groups. Data recorded from individual cervical muscles are needed to validate or refute this assumption. Methods. Eight subjects (6 males, 2 females) were exposed to seated perturbations in 8 directions. Electromyography was measured with wire electrodes inserted into the sternocleidomastoid, trapezius, levator scapulae, splenius capitis, semispinalis capitis, semispinalis cervicis, and multifidus muscles. Surface electrodes were used to measure sternohyoid activity. Muscle activity evoked by the perturbations was normalized with recordings from maximum voluntary contractions. Results. The multidirectional perturbations produced activation patterns that varied with direction within and between muscles. Sternocleidomastoid and sternohyoid activated similarly in forward and forward oblique directions. The semispinalis capitis, semispinalis cervicis, and multifidus exhibited similar spatial patterns and preferred directions, but varied in activation levels. Levator scapulae and trapezius activity generally remained low, and splenius capitis activity varied widely between subjects. Conclusion. All muscles showed muscle- and direction-specific contraction levels. Models should implement muscle- and direction-specific activation schemes during simulations of the head and neck responses to omnidirectional horizontal perturbations where muscle forces influence kinematics, such as during emergency maneuvers and low-severity crashes. Level of Evidence: N/A

[1]  Gunter P Siegmund,et al.  Are cervical multifidus muscles active during whiplash and startle? An initial experimental study , 2008, BMC musculoskeletal disorders.

[2]  Yogesh Narayan,et al.  Electromyographic and Kinematic Exploration of Whiplash-Type Neck Perturbations in Left Lateral Collisions , 2004, Spine.

[3]  J. Blouin,et al.  Head and neck control varies with perturbation acceleration but not jerk: implications for whiplash injuries , 2009, The Journal of physiology.

[4]  M. Revel,et al.  Selective electromyography of dorsal neck muscles in humans , 1997, Experimental Brain Research.

[5]  M. Schieppati,et al.  Activation of the neck muscles from the ipsi- or contralateral hemisphere during voluntary head movements in humans. A reaction-time study. , 1992, Electroencephalography and clinical neurophysiology.

[6]  Scott L. Delp,et al.  Three-dimensional spatial tuning of neck muscle activation in humans , 2002, Experimental Brain Research.

[7]  Simon C Gandevia,et al.  Spatial distribution of inspiratory drive to the parasternal intercostal muscles in humans , 2006, The Journal of physiology.

[8]  J. B. Wheeler,et al.  Cervical muscle response during whiplash: evidence of a lengthening muscle contraction. , 2000, Clinical biomechanics.

[9]  H A M Daanen,et al.  Volunteer kinematics and reaction in lateral emergency maneuver tests. , 2013, Stapp car crash journal.

[10]  Nicolás Nemirovsky,et al.  A New Methodology For Biofidelic Head-Neck Postural Control , 2010 .

[11]  Yuko Nakahira,et al.  Development of a human body finite element model with multiple muscles and their controller for estimating occupant motions and impact responses in frontal crash situations. , 2012, Stapp car crash journal.

[12]  J. Blouin,et al.  Interaction between acoustic startle and habituated neck postural responses in seated subjects. , 2007, Journal of applied physiology.

[13]  Roger W Nightingale,et al.  Improved estimation of human neck tensile tolerance: reducing the range of reported tolerance using anthropometrically correct muscles and optimized physiologic initial conditions. , 2003, Stapp car crash journal.

[14]  P. Hodges,et al.  Anticipatory postural activity of the deep trunk muscles differs between anatomical regions based on their mechanical advantage , 2014, Neuroscience.

[15]  Riender Happee,et al.  Muscle parameters for musculoskeletal modelling of the human neck. , 2011, Clinical biomechanics.

[16]  W. Hell,et al.  Muscle Activity Influence on the Kinematics of the Cervical Spine in Rear-End Sled Tests in Female Volunteers , 2013, Traffic injury prevention.

[17]  N. Teasdale,et al.  Attenuation of human neck muscle activity following repeated imposed trunk-forward linear acceleration , 2003, Experimental Brain Research.

[18]  J. Blouin,et al.  Neural control of superficial and deep neck muscles in humans. , 2007, Journal of neurophysiology.

[19]  A. Vasavada,et al.  Morphology, Architecture, and Biomechanics of Human Cervical Multifidus , 2005, Spine.

[20]  T. Szabo,et al.  Human Subject Kinematics and Electromyographic Activity During Low Speed Rear Impacts , 1996 .

[21]  Susumu Ejima,et al.  Effects of pre-impact swerving/steering on physical motion of the volunteer in the low-speed side-impact sled test , 2012 .

[22]  J. T. Inglis,et al.  Rapid neck muscle adaptation alters the head kinematics of aware and unaware subjects undergoing multiple whiplash-like perturbations. , 2003, Journal of biomechanics.

[24]  David J. Sanderson,et al.  Awareness Affects the Response of Human Subjects Exposed to a Single Whiplash-Like Perturbation , 2003, Spine.

[25]  J. Blouin,et al.  Electromyography of superficial and deep neck muscles during isometric, voluntary, and reflex contractions. , 2007, Journal of biomechanical engineering.

[26]  K. Brolin,et al.  The Effect of Muscle Activation on Neck Response , 2005, Traffic injury prevention.

[27]  Karin Brolin,et al.  Driver kinematic and muscle responses in braking events with standard and reversible pre-tensioned restraints: validation data for human models. , 2013, Stapp car crash journal.

[28]  M. Pandy,et al.  Moment arms of the human neck muscles in flexion, bending and rotation. , 2011, Journal of biomechanics.

[29]  Matthew R. Maltese,et al.  Electromyography responses of pediatric and young adult volunteers in low-speed frontal impacts. , 2013, Journal of electromyography and kinesiology : official journal of the International Society of Electrophysiological Kinesiology.

[30]  Peter Halldin,et al.  Neck Muscle Load Distribution in Lateral, Frontal, and Rear-End Impacts: A Three-Dimensional Finite Element Analysis , 2009, Spine.

[31]  K. An,et al.  Multidirectional neck strength and electromyographic activity for normal controls. , 2004, Clinical biomechanics.

[32]  Alan T Dibb,et al.  Importance of Muscle Activations for Biofidelic Pediatric Neck Response in Computational Models , 2013, Traffic injury prevention.

[33]  Susumu Ejima,et al.  A study on occupant kinematics behaviour and muscle activities during pre-impact braking based on volunteer tests , 2007 .

[34]  Jac Wismans,et al.  The Occupant Response to Autonomous Braking: A Modeling Approach That Accounts for Active Musculature , 2012, Traffic injury prevention.

[35]  D J Sanderson,et al.  Startle response of human neck muscles sculpted by readiness to perform ballistic head movements , 2001, The Journal of physiology.

[36]  de Mkj Marko Jager,et al.  A Global and a Detailed Mathematical Model for Head-Neck Dynamics , 1996 .

[37]  Karin Brolin,et al.  The importance of muscle tension on the outcome of impacts with a major vertical component , 2008 .

[38]  W. S. Monkhouse,et al.  GRAY'S ANATOMY , 1947 .

[39]  Narayan Yoganandan,et al.  Stabilizing Effect of Precontracted Neck Musculature in Whiplash , 2006, Spine.

[40]  Adam Wittek,et al.  Hill-type Muscle Model for Analysis of Mechanical Effect of Muscle Tension on the Human Body Response in a Car Collision Using an Explicit Finite Element Code , 2000 .

[41]  Marcus G Pandy,et al.  Variation of neck muscle strength along the human cervical spine. , 2004, Stapp car crash journal.

[42]  E. Batschelet Circular statistics in biology , 1981 .

[43]  Daehie Hong,et al.  Estimation of muscle response using three-dimensional musculoskeletal models before impact situation: a simulation study. , 2010, Journal of biomechanical engineering.

[44]  J. Blouin,et al.  Auditory Startle Alters the Response of Human Subjects Exposed to a Single Whiplash-like Perturbation , 2006, Spine.

[45]  V. Der,et al.  Human head neck response in frontal, lateral and rear end impact loading : modelling and validation , 2002 .

[46]  Mikhail Kuznetsov,et al.  Filtering the surface EMG signal: Movement artifact and baseline noise contamination. , 2010, Journal of biomechanics.

[47]  Shrawan Kumar,et al.  Electromyographic and Kinematic Exploration of Whiplash-Type Left Anterolateral Impacts , 2004, Journal of spinal disorders & techniques.

[48]  Gunter P Siegmund,et al.  Gradation of Neck Muscle Responses and Head/Neck Kinematics to Acceleration and Speed Change in Rear-end Collisions. , 2004, Stapp car crash journal.

[49]  Roland Örtengren,et al.  Analysis and comparison of reflex times and electromyogram of cervical muscles under impact loading using surface and fine-wire electrodes , 2001, IEEE Transactions on Biomedical Engineering.

[50]  E. Keshner,et al.  Neck muscle activation patterns in humans during isometric head stabilization , 1989, Experimental Brain Research.