Lumbar facet pain: biomechanics, neuroanatomy and neurophysiology

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Cavanaugh, John M.¹; Ozaktay, A. Cuneyt¹; Yamashita, H. Toshihiko²; King, Albert I.¹

Lumbar facet pain: biomechanics, neuroanatomy and neurophysiology

J Biomech. September 1996;29(9):1117-1129

©1996 Elsevier Science Ltd.

Affiliations

¹Wayne State University, Bioengineering Center Detroit, MI 48202, U.S.A.

²Department of Orthopaedic Surgery, Muroran City General Hospital Muroran, Hokkaido 051, Japan
Abstract and keywords

Idiopathic low back pain has confounded health care practitioners for decades. Although there has been much advance in the understanding of the biomechanics of the lumbar spine over the past 25 years, the cellular and neural mechanisms that lead to facet pain are not well understood. An extensive series of experiments was undertaken to help elucidate these mechanisms and gain a better understanding of lumbar facet pain. Biomechanic and neuroanatomic studies were performed in human cadaveric facet joints and neurophysiologic studies were performed in New Zealand White rabbits. These studies provide the following evidence to help explain the mechanisms of lumbar facet pain: (1) The facet joint can carry a significant amount of the total compressive load on the spine when the human spine is hyperextended. (2) Extensive stretch of the human facet joint capsule occurs when the spine is in the physiologic range of extreme extension. (3) An extensive distribution of small nerve fibers and free and encapsulated nerve endings exists in the lumbar facet joint capsule, including nerves containing substance P, a putative neuromodulator of pain. (4) Low and high threshold mechanoreceptors fire when the facet joint capsule is stretched or is subject to localized compressive forces. (5) Sensitization and excitation of nerves in facet joint and surrounding muscle occur when the joint is inflamed or exposed to certain chemicals that are released during injury and inflammation. (6) Marked reduction in nerve activity occurs in facet tissue injected with hydrocortisone and lidocaine. Thus, the facet joint is a heavily innervated area that is subject to high stress and strain. The resulting tissue damage or inflammation is likely to cause release of chemicals irritating to the nerve endings in these joints, resulting in low back pain.

Keywords: Low back pain; Facet joint: Nociceptors: Inflammation; Substance P.
Links

DOI: 10.1016/0021-9290(96)00023-1

PubMed: 8872268

WoS: A1996VD99800001
History

Revised: 1995-12-15

Cited Works (6)

Year	Entry
1974	Prasad P, King AI, Ewing CL. The role of articular facets during +G_z acceleration. J Appl Mech. June 1974;41(2):321-326.
1992	Avramov AI, Cavanaugh JM, Ozaktay CA, Getchell TV, King AI. The effects of controlled mechanical loading on group-II, III, and IV afferent units from the lumbar facet joint and surrounding tissue: an in vitro study. J Bone Joint Surg. December 1992;74A(10):1464-1471.
1989	Cavanaugh JM, El‐Bohy A, Hardy WN, Getchell TV, Getchell ML, King AI. Sensory innervation of soft tissues of the lumbar spine in the rat. J Orthop Res. May 1989;7(3):378-388.
1984	Yang KH, King AI. Mechanism of facet load transmission as a hypothesis for low-back pain. Spine. September 1984;9(6):557-565.
1990	Yamashita T, Cavanaugh JM, el-Bohy AA, Getchell TV, King AI. Mechanosensitive afferent units in the lumbar facet joint. J Bone Joint Surg. July 1990;72A(6):865-870.
1989	El-Bohy AA, Yang K-H, King AI. Experimental verification of facet load transmission by direct measurement of facet lamina contact pressure. J Biomech. 1989;22(8-9):931-941.

Cited By (29)

Year	Entry
2015	King AI. Introduction to and applications of injury biomechanics. In: Yoganandan N, Nahum AM, Melvin JW, eds. Accidental Injury: Biomechanics and Prevention. 3rd ed. New York: Springer; 2015:1-31.
2004	Lee KE, Franklin AN, Winkelstein BA. Development of an experimental model of in vivo cervical facet joint loading and capsule distraction. In: Proceedings of the 32nd International Workshop on Human Subjects for Biomechanical Research. 2004.257-267.
2008	Quinn KP, Winkelstein BA. Regional changes in collagen fiber alignment may identify the onset of damage in the facet capsular ligament. In: Proceedings of the 36th International Workshop on Human Subjects for Biomechanical Research. November 2, 2008; San Antonio, TX.
1999	Winkelstein BA, Nightingale RW, Richardson WJ, Myers BS. Cervical facet joint mechanics: its application to whiplash injury. In: Proceedings of the 43rd Stapp Car Crash Conference. October 25-27, 1999; San Diego, CA. Warrendale, PA: Society of Automotive Engineers:243-252. SAE 99SC15.
2004	Lee KE, Davis MB, Mejilla RM, Winkelstein BA. In vivo cervical facet capsule distraction: mechanical implications for whiplash and neck pain. Stapp Car Crash J. 2004;48:373-395. SAE 2004-22-0016.
2005	Lu Y, Chen C, Kallakuri S, Patwardhan A, Cavanaugh JM. Neural response of cervical facet joint capsule to stretch: a study of whiplash pain mechanism. Stapp Car Crash J. 2005;49:49-65. SAE 2005-22-0003.
2007	Quinn KP, Lee KE, Ahaghotu CC, Winkelstein BA. Structural changes in the cervical facet capsular ligament: potential contributions to pain following subfailure loading. Stapp Car Crash J. 2007;51:169-187. SAE 2007-22-0008.
2001	Winkelstein BA, McLendon RE, Barbir A, Myers BS. An anatomical investigation of the human cervical facet capsule, quantifying muscle insertion area. J Anat. April 2001;198(4):455-461.
2004	Pollintine P, Przybyla AS, Dolan P, Adams MA. Neural arch load-bearing in old and degenerated spines. J Biomech. February 2004;37(2):197-204.
2006	Lee KE, Franklin AN, Davis MB, Winkelstein BA. Tensile cervical facet capsule ligament mechanics: failure and subfailure responses in the rat. J Biomech. 2006;39(7):1256-1264.
2023	Singh S, Winkelstein BA. Characterization of the L4/L5 rat facet capsular ligament macromechanical and microstructural responses to tensile failure loading. J Biomech. August 2023;157:111742.
2011	Jaumard NV, Welch WC, Winkelstein BA. Spinal facet joint biomechanics and mechanotransduction in normal, injury and degenerative conditions. J Biomech Eng. July 2011;133(7):071010.
2004	Lee KE, Thinnes JH, Gokhin DS, Winkelstein BA. A novel rodent neck pain model of facet-mediated behavioral hypersensitivity: implications for persistent pain and whiplash injury. J Neurosci Meth. August 30, 2004;137(2):151-159.
2000	Winkelstein BA, Nightingale RW, Richardson WJ, Myers BS. The cervical facet capsule and its role in whiplash injury: a biomechanical investigation. Spine. May 15, 2000;25(10):1238-1246.
2004	Stemper BD, Yoganandan N, Pintar FA. Gender- and region-dependent local facet joint kinematics in rear impact: implications in whiplash injury. Spine. October 15, 2004;29(16):1764-1771.
2020	Sloan SR Jr. Tissue-Engineered Annulus Fibrosus Repair and Nucleus Pulposus Augmentation in Pre-Clinical Models of Intervertebral Disc Degeneration [PhD thesis]. Ithaca, NY: Cornell University; May 2020.
1999	Winkelstein BA. A Mechanical Basis for Whiplash Injury: The Cervical Facet Joint, Spinal Motion Segment, and Combined Loading [PhD thesis]. Duke University; 1999.
2004	Stemper BD. Whiplash Affects Cervical Spine Biomechanics [PhD thesis]. Marquette University; May 2004.
2007	Hoops HE. The Neuromuscular Response of the Lumbar Spine to Varying Rest Durations Between Cyclic Flexion Periods [Master's thesis]. Colorado School of Mines; 2007.
2015	Campbell JQ. Population-Based Methods to Evaluate the Effect of Anatomical Variation on Lumbar Spine Biomechanics [PhD thesis]. Colorado School of Mines; 2015.
2000	Doehring TC. Delineation of in-Vitro Lumbar Spine Structural Properties Using a Robotic/UFS Testing System With Hybrid Control: Experiments and Analytical Simulation [PhD thesis]. University of Pittsburgh; 2000.
2020	Klahsen O. Understanding the Impact of Muscle and Bony Injury in the Lumbar Spine: How Multifidus Muscle and Facet Joint Damage Impact Muscle Architecture and Joint Degeneration in the Rat [Master's thesis]. University of Guelph; December 2020.
2008	Lee KE. An Engineering Approach to Understanding Painful Facet -Mediated Injury: Insights on Biomechanics and Neuropeptide Responses in a Rat Model [PhD thesis]. Philadelphia, PA: University of Pennsylvania; 2008.
2010	Quinn KP. Integrating Electrophysiological, Mechanical, and Optical Methods to Define the Mechanisms of Painful Facet Joint Injury [PhD thesis]. Philadelphia, PA: University of Pennsylvania; 2010.
2015	Kras JV. The Role of Intra-Articular Nerve Growth Factor in Facet-Mediated Pain: Relationships to Spinal BDNF and Neuronal Hyperexcitability [PhD thesis]. Philadelphia, PA: University of Pennsylvania; 2015.
2008	Drake JDM. Axial Twist Loading of the Spine: Modulators of Injury Mechanisms and the Potential for Pain Generation [PhD thesis]. University of Waterloo; 2008.
2010	Dunk NM. Time-Varying Changes in the Lumbar Spine from Exposure to Sedentary Tasks and Their Potential Effects on Injury Mechanics and Pain Generation [PhD thesis]. University of Waterloo; 2010.
2011	Howarth SJ. Mechanical Response of the Porcine Cervical Spine to Acute and Repetitive Anterior-Posterior Shear [PhD thesis]. University of Waterloo; 2011.
2020	Fewster KM. Exploring Low to Moderate Velocity Motor Vehicle Rear Impacts as a Viable Injury Mechanism in the Lumbar Spine [PhD thesis]. University of Waterloo; 2020.