Development of a system for in vitro neck muscle force replication in whole cervical spine experiments

Panjabi, Manohar M.<sup>1</sup>; Miura, Takehiko<sup>1,2</sup>; Cripton, Peter A.<sup>1</sup>; Wang, Jaw-Lin<sup>1,3</sup>; Nain, Amrinder S.<sup>1</sup>; DuBois, Christian<sup>1</sup>

Affiliations

¹Biomechanics Research Laboratory, Department of Orthopaedics and Rehabilitation, Yale University School of Medicine, New Haven, Connecticut

²Department of Orthopaedic Surgery, St. Marianna University School of Medicine, Kanagawa, Japan

³Institute of Biomedical Engineering, National Taiwan University, Taipei, Taiwan

Abstract and keywords

Study Design: An in vitro biomechanical study.

Objectives: To develop and evaluate a new in vitro whole cervical spine model that provides to the specimen, in vivo-like mechanical characteristics.

Summary of Background Data: In vitro studies of kinematics, kinetics, and trauma using isolated spine specimens (head–T1 vertebra) have usually applied upward force to the head, resulting in tensile spine forces, contrary to the physiological compressive forces present in vivo. Further, the in vitro load-displacement curves have never been compared with the corresponding in vivo data.

Methods: A novel muscle force replication (MFR) system is presented. It consists of a set of compressive forces applied to the various vertebrae and occiput of a whole cervical spine specimen. Two protocols, with and without MFR, were evaluated using standardized flexibility testing. Ranges of motion (ROM) and load-displacement curves were documented, and contrasted with similar in vivo data.

Results: Results for the MFR were found to be similar to the in vivo measurements, with respect to the intersegmental and whole neck motions as well as the load-displacement curves, thus validating the MFR approach.

Conclusions: The new model advances the in vitro testing, which uses whole cervical spine specimens.

Keywords: in vitro models; whole cervical spine; axial preload; biomechanics

Links

DOI: 10.1097/00007632-200110150-00012

PubMed: 11598511

WoS: 000171559100010

History

Received: 2000-12-22

Revised: 2001-03-15

Accepted: 2001-03-19

Cited Works (10)

Year	Entry
1988	Moroney SP, Schultz AB, Miller JAA. Analysis and measurement of neck loads. J Orthop Res. September 1988;6(5):713-720.
1998	Panjabi MM, Cholewicki J, Nibu K, Babat LB, Dvorak J. Simulation of whiplash trauma using whole cervical spine specimens. Spine. January 1998;23(1):17-24.
1999	Patwardhan AG, Havey RM, Meade KP, Lee B, Dunlap B. A follower load increases the load-carrying capacity of the lumbar spine in compression. Spine. May 15, 1999;24(10):1003-1009.
2000	Patwardhan AG, Havey RM, Ghanayem AJ, Diener H, Meade KP, Dunlap B, Hodges SD. Load-carrying capacity of the human cervical spine in compression is increased under a follower load. Spine. June 15, 2000;25(12):1548-1554.
1991	Amevo B, Worth D, Bogduk N. Instantaneous axes of rotation of the typical cervical motion segments: a study in normal volunteers. Clin Biomech (Bristol, Avon). May 1991;6(2):111-117.
1981	Tencer AF, Ahmed AM. The role of secondary variables in the measurement of the mechanical properties of the lumbar intervertebral joint. J Biomech Eng. August 1981;103(3):129-137.
1991	Dvorak J, Panjabi MM, Novotny JE, Antinnes JA. In vivo flexion/extension of the normal cervical spine. J Orthop Res. November 1991;9(6):828-834.
1998	Panjabi MM, Cholewicki J, Nibu K, Grauer J, Babat LB, Dvorak J. Critical load of the human cervical spine: an in vitro experimental study. Clin Biomech (Bristol, Avon). January 1998;13(1):11-17.
1989	Lind B, Sihlbom H, Nordwall A, Malchau H. Normal range of motion of the cervical spine. Arch Phys Med Rehabil. September 1989;70(9):692-695.
1998	Lund T, Oxland TR, Jost B, Cripton P, Grassmann S, Etter C, Nolte L-P. Interbody cage stabilisation in the lumbar spine: biomechanical evaluation of cage design, posterior instrumentation and bone density. J Bone Joint Surg. March 1998;80B(2):351-359.

Cited By (15)

Year	Entry
2008	Van Toen C, Nelson TS, Jones CF, Street J, Cripton PA. Development of an in vitro model of head-first impact with a Hybrid III head, surrogate spinal cord, and simulated neck muscles. In: Proceedings of the 36th International Workshop on Human Subjects for Biomechanical Research. November 2, 2008; San Antonio, TX.
2009	Van Toen C, Jones CF, Nelson TS, Street J, Cripton PA. Simulation of head-first impact using cervical spine specimens, simulated neck muscles, and a Hybrid III ATD head. In: Proceedings of the 5th Ohio State University Injury Biomechanics Symposium. May 17-19, 2009; Columbus, OH.
2004	Ivancic PC, Pearson AM, Panjabi MM, Ito S. Injury of the anterior longitudinal ligament during whiplash simulation. Eur Spine J. 2004;13(1):61-68.
2008	Brolin K, Hedenstierna S, Halldin P, Bass C, Alem N. The importance of muscle tension on the outcome of impacts with a major vertical component. Int J Crashworthiness. October 2008;13(5):487-498.
2011	Panzer MB, Fice JB, Cronin DS. Cervical spine response in frontal crash. Med Eng Phys. November 2011;33(9):1147-1159.
2004	Ito S, Ivancic PC, Panjabi MM, Cunningham BW. Soft tissue injury threshold during simulated whiplash: a biomechanical investigation. Spine. May 1, 2004;29(9):979-987.
2010	Nelson TS, Cripton PA. A new biofidelic sagittal plane surrogate neck for head-first impacts. Traffic Inj Prev. June 2010;11(3):309-319.
2013	Bell KM. Development of a Physiologic in-Vitro Testing Methodology for Assessment of Cervical Spine Kinematics [PhD thesis]. University of Pittsburgh; 2013.
2007	Saari A. Spinal Cord Deformation During Axial Impact Injury of the Cervical Spine [Master's thesis]. Vancouver, BC: University of British Columbia; January 2007.
2011	Nelson TS. Towards a Neck Injury Prevention Helmet for Head-First Impacts: A Mechanical Investigation [PhD thesis]. Vancouver, BC: University of British Columbia; December 2011.
2012	Boak JC. Effects of Age Related Degeneration on Cervical Spine Mechanics [Master's thesis]. Vancouver, BC: University of British Columbia; September 2012.
2014	Newell R. Are Inversion, Posture, Motion and Muscle Effects Important to Spinal Alignment? [PhD thesis]. Vancouver, BC: University of British Columbia; April 2014.
2015	Thomson V. Furthering the Pro-Neck-Tor Helmet Technology Through Multibody Modeling and Design [Master's thesis]. Vancouver, BC: University of British Columbia; August 2015.
2020	Fonseca G. Development of a Functional Spinal Unit for Evaluation of Sports and Automotive Protective Equipment [Master's thesis]. Vancouver, BC: University of British Columbia; April 2020.
2006	Ivancic PC. Cervical Spine Injury During Simulated Automobile Collisions [PhD thesis]. Yale University; May 2006.