As described above, consistent with the pathophysiologic hypothesis that persistent symptoms after MVC result from abnormal neck motion, most studies evaluating neurobiological mechanisms of post-MVC pain pathogenesis have focused on the neck. A peripheral nociceptive input is capable of dynamically maintaining chronic pain over a broader local area [21]; tissue structures that might provide an ongoing source of nociceptive input are many, including the zygapophysial joint capsule, anuli fibrosi, and various ligaments, muscles, and intra-articular structures [12]. The best studied of these candidate structures is the zygapophysial joint. A small randomized controlled trial of radiofrequency neurotomy of zygapophysial joint cervical medial branch nerves in 24 patients with chronic neck pain after MVC found that the intervention group had substantially improved neck pain outcomes. In addition, several small, nonrandomized observational case series also suggest a potential treatment benefit [1, 30]. A transient peripheral tissue injury might also result in the development of persistent post-MVC pain, if this transient injury caused peripheral and/or central sensitization that then became self-sustaining. Whether such a phenomenon accounts for persistent post-MVC pain development in some individuals is unknown.

These data suggest that peripheral tissue injury may contribute to chronic post-MVC pain in some individuals. However, as already described, important features of common post-MVC symptom phenotypes are poorly explained by cervicogenic mechanisms, including the typical occurrence of pain in body regions distant from the neck, the common prevalence of widespread pain, and the often multidimensional nature of the phenotype, of which pain symptoms are only one part. In addition, if injury-related damage to cervical structures occurring at the
moment of MVC played a dominant role in the genesis of post-MVC pain symptoms, then in epidemiologic studies, collision-related characteristics (e.g., vehicle speed, direction of collision, amount of vehicle damage) would be expected to be important risk factors for chronic post-MVC pain development. In study after study, however, collision-related factors have consistently been shown to be poor predictors of post-MVC pain outcomes [3, 6, 7, 10, 11, 17, 24, 26, 33, 44, 45]. Biomechanical experts frequently argue that this lack of association is due to the inability of epidemiologic studies to capture all of the subtleties of individual crash histories, such as the degree of neck flexion or extension at the moment of impact, the degree of lateral rotation of the neck at the moment of impact, and the distance of the head from the car head restraint. This is not a valid reason to discount epidemiologic study results, however, for while no study evaluates every potentially relevant variable, unless a consistent relationship exists between an important unmeasured third variable and measured variable(s), the relationship between the measured variable and outcome is unaffected. For example, cigarette smoking has consistently been shown to be a dominant risk factor for lung cancer development even though epidemiologic studies identifying this association have never accounted for all of the subtleties of individual cigarette smoking histories, such as cigarette brand, proportion of time spent smoking indoors versus outdoors, method of holding cigarette and inhaling, proportion of time that smoker tends to leave cigarette burning in ashtray versus smoking, secondhand smoke exposure, etc. If MVC-related tissue injury played a central role in the pathogenesis of post-MVC pain, then collision-related factors should be dominant predictors of pain outcomes. But they are not.